JP2019026426A - Roll sheet feeding device - Google Patents

Abstract

To provide a roll sheet feeding device capable of preventing an eccentric rotation due to a deformation of a roll sheet fixing member and positively fixing a roll sheet in a short time.SOLUTION: A roll sheet feeding device comprises a roll sheet insertion shaft 9 that is in a hollow cylindrical form and rotatably holding a roll sheet 5 on an outer periphery, three blades 11 that consist of elongate tabular members parallel to an axis of the roll sheet insertion shaft 9 and are provided to protrude from an outer periphery of the shaft 9, a slider 17 that is provided movable in the axial direction of the shaft 9 and moves the blades 11 radially outwardly, and a knob 13 that moves the slider 17 in an axial direction. As the slider 17 is axially moved by a manipulation of the knob 13, the blades 11 move radially outwardly of the shaft 9 and protrude from an outer periphery of the shaft 9 so as to fix the roll sheet 5.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a roll paper supply device that supplies roll paper to a printing apparatus.

  A conventional roll paper supply device is provided with a roll paper tube holding device that detachably holds the roll paper.

  In this roll paper tube holding device, a thin elastic member is protruded from the roll paper tube insertion shaft using a switching mechanism such as a lever by operating the operation unit, and is brought into contact with the inside of the roll paper tube. There were some which fixed (for example, refer to JP, 9-240094, A (patent documents 1)).

Japanese Patent Laid-Open No. 9-240094

However, since the roll paper tube holding device of the conventional roll paper supply device has a predetermined amount of protrusion of the roll paper fixing member made of an elastic member, it varies depending on the variation in inner diameter for each type of roll paper tube. In addition to being unable to keep the holding force of the roll paper tube constant, there was a problem that when the inner diameter of the roll paper tube was large, the holding force was lowered and the roll paper tube could not be fixed securely.
In addition, since the roll paper tube is fixed by the elastic member, the elastic member is deformed by the weight of the roll paper, so that the rotation center of the roll paper tube insertion shaft and the roll paper tube is shifted, thereby the roll There is a problem that the paper rotates eccentrically and the conveyance of the roll paper becomes unstable, and the printing quality in the printing apparatus is lowered.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a roll paper supply apparatus that can maintain such a contact force between a roll paper fixing member and a roll paper tube constant. .

  In order to solve the above problems, a roll paper supply device according to the present invention described in claim 1 is a roll paper supply device that holds roll paper and supplies the roll paper to another device, which is a hollow cylindrical shape, and is cylindrical. A roll paper insertion shaft that rotatably holds the roll paper on the outer periphery of the roll paper, and is housed inside the roll paper insertion shaft, and is formed of a long plate-like member parallel to the axis of the roll paper insertion shaft, A roll paper fixing member provided so as to be able to protrude from the outer periphery of the roll paper insertion shaft, and housed in the roll paper insertion shaft, provided to be movable in the axial direction of the roll paper insertion shaft, An axial movement means for moving the roll paper fixing member radially outward; and an operation unit provided at one axial end of the roll paper insertion shaft and moving the axial movement means in the axial direction. The fixing member is the aforementioned operation In accordance with the operation, the axial movement means moves in the radial direction of the roll paper insertion shaft, protrudes from the outer periphery of the roll paper insertion shaft, and fixes the roll paper. .

  According to the present invention, the roll paper fixing member made of a long plate-like member parallel to the shaft is provided so as to protrude radially outward to fix the roll paper. It is possible to provide a roll paper supply device that can fix the roll paper 5 and can prevent eccentric rotation of the roll paper due to deformation of the roll paper fixing member.

It is a perspective view of the roll paper supply apparatus regarding 1st Embodiment. It is explanatory drawing which shows the structure of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is a partially cutaway exploded perspective view showing the periphery of the blade regulating member of the roll paper tube holding device in the roll paper supply device according to the first embodiment. It is a partially cutaway exploded perspective view showing a modified example of the blade regulating member of the roll paper tube holding device in the roll paper supply device relating to the first exemplary embodiment. It is a disassembled perspective view of the periphery of the slider of the roll paper tube holding device in the roll paper supply device according to the first embodiment. It is explanatory drawing of the modification of the braid | blade of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is a disassembled perspective view which shows the fixation structure of the screw shaft of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is a functional block diagram of the roll paper tube holding device in the roll paper supply device relating to the first exemplary embodiment. It is operation | movement explanatory drawing which shows the releasing operation | movement of roll paper fixation of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is operation | movement explanatory drawing which shows the roll paper loading operation | movement of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is operation | movement explanatory drawing which shows the roll paper removal operation | movement of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 1st Embodiment. It is explanatory drawing which shows the structure of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 2nd Embodiment. It is a disassembled perspective view of the periphery of the socket of the roll paper tube holding device in the roll paper supply device according to the second embodiment. It is HH sectional drawing of the roll paper tube holding | maintenance apparatus shown in FIG. It is a functional block diagram of the roll paper tube holding device in the roll paper supply device according to the second embodiment. It is operation | movement explanatory drawing which shows the roll paper loading operation | movement of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 2nd Embodiment. It is operation | movement explanatory drawing which shows the roll paper removal operation | movement of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding 2nd Embodiment. It is explanatory drawing which shows the structure of the socket periphery of the roll paper tube holding | maintenance apparatus in the roll paper supply apparatus regarding the modification 1 of 2nd Embodiment.

(First embodiment)
The first embodiment, which is the best mode for carrying out the present invention, will be described below. Elements common to the drawings are given the same reference numerals. First, the configuration of the roll paper supply device according to the first embodiment will be described. FIG. 1 is a perspective view of a roll paper supply apparatus according to the first embodiment.

  The roll paper supply device 1 holds the roll paper 5 and supplies the roll paper 5 to a printing device 25 as another device. The roll paper supply device 1 includes a roll paper holding unit 2 and a roll paper transport unit 3. The roll paper holding unit 2 includes a roll paper holding device 4 and a shaft fixing unit 30. The roll paper holding device 4 rotatably holds the roll paper 5 on a roll paper tube insertion shaft 9 as a roll paper insertion shaft, which will be described later, and the shaft fixing portion 30 can rotate a shaft 8 which will be described later of the roll paper holding device 4. Fix it. The roll paper 5 is sandwiched between left and right flanges 12-1, 12-2, which will be described later, that is, a fixed end side flange 12-1 on the shaft fixing portion 30 side and a free end side flange 12-2 opposite thereto. Is done. Then, the roll paper holding device 4 rotates the roll paper 5 in the arrow K direction and feeds it to the roll paper transport unit 3.

  The roll paper transport unit 3 includes a transport roller 6 and a cutter device 7. The transport roller 6 takes in the roll paper 5 from the roll paper holding device 4 and transports it in the direction of arrow A as a strip-shaped roll paper 5b. The cutter device 7 is provided on the downstream side of the conveyance roller 6 in the conveyance direction, and cuts the strip-shaped roll paper 5b to a desired length. The roll paper 5 may be composed of the roll paper tube 5a (see FIG. 10) and the belt-shaped roll paper 5b wound around the roll paper tube 5a, or may be composed only of the belt-shaped roll paper 5b. It may be a thing.

  With the above configuration, the roll paper supply device 1 supplies the belt-shaped roll paper 5b to the printing device 25 as another device arranged downstream in the transport direction. Then, the printing device 25 prints an image such as a character on the belt-like roll paper 5b. The roll paper tube holding device 4 has a lock portion 23 composed of a lock lever or the like, and the lock portion 23 can lock the movement of the roll paper tube holding device 4 in the direction opposite to the arrow X direction. It is like that.

  Next, the configuration of the roll paper tube holding device 4 in the roll paper supply device 1 according to the first embodiment will be described. FIG. 2 is an explanatory diagram illustrating the configuration of the roll paper tube holding device in the roll paper supply device according to the first embodiment. 2A is a front view seen from the free end side, that is, from the direction of the arrow X shown in FIG. 1, and FIG. 2B is a YY sectional view shown in FIG. 2 and the subsequent drawings, the flange 12-2 on the free end side, the lock portion 23, and the roll paper 5 are not shown.

  As shown in FIG. 2A, in the roll paper tube holding device 4, a cap 10 described later is provided on the free end side, and further, a knob 13 is provided rotatably thereabove. The cap 10 has the same diameter as a roll paper tube insertion shaft 9 described later. As will be described later, the roll paper tube holding device 4 rotates a screw shaft 14 to be described later by rotating a knob 13, and slits 9 s provided at equal intervals on the outer periphery of the roll paper tube insertion shaft 9. It is the structure made to protrude.

  As shown in FIG. 2B, the roll paper tube holding device 4 is configured to pass the shaft 8 through the center hole of the flange 12-1 and the shaft holding hole 9 b provided in the roll paper tube insertion shaft 9. . The shaft 8 has a D-cut section, and a fixed end on the flange 12-1 side, that is, an end on the left side in the figure is rotatably supported by the shaft fixing unit 30. By adopting such a configuration, the roll paper tube holding device 4 can rotate integrally around the shaft 8.

  A roll paper tube insertion shaft 9 as a roll paper insertion shaft has a hollow cylindrical shape, and the roll paper 5 is rotatably held on the outer periphery of the cylindrical paper. The roll paper 5 is provided with left and right flanges 12-1, 12-2 ( 1). The flange 12-1 side is a fixed end, and the flange 12-2 side is a free end. The roll paper 5 with the roll paper tube 5a can be inserted by removing the flange 12-2 on the free end side.

  A roll paper tube insertion shaft 9 as a roll paper insertion shaft is provided with a plurality of blade regulating members 19 as regulating members having a plurality of inclined portions 19a in the axial direction along the outer periphery. The plurality (two in the figure) of inclined portions 19a are configured to abut against a plurality (two in the figure) of blade regulating force receiving portions 11a of the blade 11 as a roll paper fixing member.

  The inclined portion 19a has a longer distance from the center of the roll paper tube insertion shaft 9 toward the fixed end, that is, is higher, and the blade regulating force receiving portion 11a that contacts the inclined portion 19a is in the fixed end direction. When moving in the C direction, the blade 11 moves in the arrow G direction as the radially outer side of the roll paper tube insertion shaft 9. Since the inclined portion 19a and a plurality of blade regulating force receiving portions 11a that are in contact with the inclined portion 19a are provided along the roll paper tube insertion shaft 9, the inner side of the roll paper 5 is securely fixed by the blade 11 over substantially the entire surface in the axial direction. be able to.

Further, a plurality of blades 11 and blade regulating members 19 provided along the outer periphery are equally spaced in the direction in which the roll paper tube insertion shaft 9 rotates (hereinafter referred to as “rotation direction”), that is, at an interval of about 120 degrees. 3 each. As a result, the roll paper 5 can be fixed by the plurality of blades 11, so that the roll paper 5 can be prevented from rotating eccentrically.
As will be described later, three slits 9s are provided on the outer periphery of the roll paper tube insertion shaft 9 so that the three blades 11 can protrude. The blade 11 is generated by sheet metal processing, and the roll paper tube insertion shaft 9 is connected to the blade restricting member 19 and the shaft holding hole 9b at the fixed end on the shaft fixing portion 30 side, that is, the left end in the figure, and is made of a resin mold such as plastic. Can be integrally molded.

  The cap 10 has a cylindrical shape composed of a disk and a circumferential side surface, and is fixed to the free end side of the roll paper tube insertion shaft 9. The slider 17 can move in the cap 10 along the circumferential side surface, that is, in the axial direction. A limiter 10a that restricts the movement of the slider 17 toward the free end, that is, the movement in the direction opposite to the arrow C direction, is provided inside the disc of the cap 10.

  The blade 11 is constituted by an elongated plate-like member that is accommodated inside, that is, inside, the outer periphery of the roll paper tube insertion shaft 9 and is disposed in parallel to the roll paper tube insertion shaft 9. The blade 11 is provided so as to be movable in the axial direction. The state shown in FIG. 2B is the case where the blade outer end 11c of the blade 11 is housed inside the roll paper tube insertion shaft 9, and before the inner side of the roll paper tube 5a (see FIG. 10) abuts. Shows the state.

The blade 11 is provided so as to protrude in the arrow G direction as the radially outer side of the roll paper tube insertion shaft 9 and in a state parallel to the shaft. The blade 11 is disposed such that the plate width direction of the plate-like blade 11 is the radial direction. That is, the blade outer end 11c of the plate-like blade 11 is positioned on the radially outer side as one long side end, and the blade regulating force receiving portion 11a is positioned on the radially inner side. As a result, the blade 11 has a strong durability against an external force received from the plate width direction, that is, an external force received from the radial direction of the roll paper tube insertion shaft 9, and is not easily deformed.
The outer side of the blade 11 in the radial direction is a linear blade outer end along the roll paper tube insertion shaft 9 so as to project from slits 9s as projecting openings provided at equal intervals on the outer periphery of the roll paper tube insertion shaft 9. 11c is configured.

  The inner side of the roll paper tube insertion shaft 9 in the radial direction constitutes a blade restricting force receiving portion 11 a formed by bending the blade 11. The blade regulating force receiving portion 11a has a surface substantially perpendicular to the plate-like blade body 11e (see FIG. 5). The blade restricting force receiving portion 11a has a longer distance from the center of the roll paper tube insertion shaft 9 toward the fixed end, that is, is inclined and becomes higher, and an inclined portion 19a provided on the blade restricting member 19 is provided. By setting the same inclination angle as that in FIG.

  By moving in the axial direction, the blade 11 can move in the radial direction by contact with the inclined portion 19a. The blade outer end 11 c of the blade 11 engages with a slit 9 s described later of the roll paper tube insertion shaft 9. A post 11b as a fulcrum provided on the free end side of the blade 11 is engaged with a long hole 17a shown in FIG. The flange 12-1 is fixed to the roll paper insertion shaft 9.

  The knob 13 is provided on the free end side as one end of the roll paper tube insertion shaft 9 in the axial direction, and rotates the screw shaft 14. A torque limiter 15 is attached to the knob 13, and the torque limiter 15 rotates integrally with the knob 13. The outer diameter L of the knob 13 is made smaller than the roll paper tube 5a so that the roll paper tube 5a (see FIG. 10) described later can be passed when the roll paper 5 is loaded.

  The torque limiter 15 is configured such that the screw shaft 14 rotates integrally with the torque limiter 15 via a pin 16 (see FIG. 7) described later. The torque limiter 15 has a function of interrupting torque transmission when a load equal to or higher than a predetermined torque is applied, and may be a mechanical type or a magnet type. By providing the torque limiter 15 as described above, when the torque transmitted from the knob 13 to the screw shaft 14 exceeds a predetermined torque, torque transmission due to the rotation of the knob 13 is interrupted, and the screw shaft 14 does not rotate and the knob is not rotated. 13 idles. Hereinafter, this predetermined torque is referred to as “transmission cutoff torque”.

  The rotation of the screw shaft 14 is transmitted from the knob 13 to move the slider 17 in the axial direction. The screw shaft 14 is an extension of the roll paper tube insertion shaft 9 and is formed at a distance from the knob 13 to the slider 17, and a screw portion 14a is provided at one end portion (left end in the figure) as a fixed end side. . The screw shaft 14 is inserted into the hole of the torque limiter 15 and the knob 13 at the other end as the free end side, and is fixed by a stopper 21. The screw portion 14 a of the screw shaft 14 has a left-handed configuration, and is configured to mesh with the nut 18 within the movement range of the slider 17. As will be described later, the slider 17 is configured to move integrally with the nut 18 and the like.

  The configuration of the roll paper tube holding device 4 in the roll paper supply device 1 according to the first embodiment will be described in more detail. FIG. 3 is a partially cutaway exploded perspective view showing the periphery of the blade regulating member of the roll paper tube holding device in the roll paper supply device according to the first embodiment. In FIG. 3, the blade 11 is not shown. As shown in FIG. 3, inside the roll paper tube insertion shaft 9, a blade restricting member 19 having an inclined portion 19a that abuts against the blade restricting force receiving portion 11a (see FIG. 5) of the blade 11 is substantially in the rotational direction. Three are provided evenly, that is, about every 120 degrees.

  A shaft holding hole 9 b through which the shaft 8 passes is provided at the axis of the roll paper tube insertion shaft 9. Further, on the outer periphery of the roll paper tube insertion shaft 9, there are provided three slits 9s as projecting openings for projecting the blade outer end 11c of the blade 11 from the outer periphery. The slit 9 s is formed in parallel with the roll paper tube insertion shaft 9 and long in the width direction of the roll paper 5. Thereby, since the three blades 11 contact | abut to the inner periphery of the roll paper pipe | tube 5a in the circumferential direction, the roll paper 5 can be fixed with sufficient balance.

Then, the shaft 8 is passed through the center hole of the flange 12-1 and the shaft holding hole 9b of the roll paper tube insertion shaft 9, and the flange 12-1 and the roll paper insertion shaft 9 are fixed by the fixing screw 12a and the fixing hole 9e. The flange 12-1, the roll paper insertion shaft 9, the blade regulating member 19, and the shaft holding hole 9b may be integrally formed instead of being fixed by the fixing screw 12a.
The cap 10 has a blade 11, a slider 17, and a limiter 10 a for restricting the movement of the slider 17 attached to the inside of the cap 10, and is fixed to the right end of the roll paper tube insertion shaft 9 in the drawing by a fixing screw 10 a and a fixing hole 9 f. .

  FIG. 4 is a partially cutaway exploded perspective view showing a modified example of the blade regulating member of the roll paper tube holding device in the roll paper supply device according to the first embodiment. In FIG. 4, the blade 11 is not shown. In the blade restricting member 19 shown in FIG. 3 described above, the blade restricting member 19 is separated from each other at three locations. However, in the blade restricting member 49 of this modification, a single cylindrical blade restricting member 49 is disposed. It has become. In this way, by forming the inclined portion 49a of the blade regulating member 49 on the entire surface in the rotational direction, the thickness of the blade 11 brought into contact with the inclined portion 49a can be reduced. Even if the mounting accuracy of the blade 11 is low, the inclined portion 49a of the blade regulating member can be reliably brought into contact.

  Also in this case, the shaft 8 is passed through the hole of the flange 12-1 and the shaft holding hole 29b of the roll paper tube insertion shaft 29, and the flange 12-1 and the roll paper insertion shaft 29 are fixed by the fixing screw 12a and the fixing hole 29e. The cap 10 is similarly fixed by the fixing screw 10a and the fixing hole 29f.

  FIG. 5 is an exploded perspective view of the periphery of the slider of the roll paper tube holding device in the roll paper supply device according to the first embodiment. As shown in FIG. 5, the blade 11 provided with the blade restricting force receiving portion 11 a has a post 11 b provided on the right end in the drawing as the free end side of the roll paper tube holding device 4, on the free end side of the slider 17. It is attached by engaging with a long hole 17a provided in the. The long hole 17a is long toward the center of the roll paper tube insertion shaft 9 and has a length corresponding to the length in which the blade 11 is moved in the arrow G direction by the inclined portion 19a of the blade regulating member 19. . Similarly, the posts 11b of the respective blades 11 are also engaged and attached to the other two long holes 17a arranged substantially equally in the rotation direction (arrow K direction).

These blades 11 are inserted between the roll paper tube insertion shaft 9 (see FIG. 2B) and the blade restricting member 19, and the blade restricting force receiving portion 11a is an inclined portion of the blade restricting member 19 at the broken line a. It is attached so as to abut on 19a.
On the other hand, the screw shaft 14 is attached so that the screw portion 14 a at the tip is engaged with the nut 18 of the slider 17. As described above, the slider 17 is attached together with the three blades 11, the blade regulating member 19, and the screw shaft 14 so as to be able to rotate in the arrow K direction with the center of the nut 18 as a support shaft.

  FIG. 6 is an explanatory diagram of a modified example of the blade of the roll paper tube holding device in the roll paper supply device according to the first embodiment. Although the blade 11 shown in FIG. 5 has a shape including the blade regulating force receiving portion 11a, the blade 41 as a modified example is provided with a blade regulating force receiving portion 41d instead of the blade regulating force receiving portion 11a. It is good also as a shape. The blade restricting force receiving portion 41d has a longer distance from the center of the roll paper tube insertion shaft 9 toward the fixed end on the inner side in the radial direction of the roll paper tube insertion shaft 9, that is, is inclined. By setting the inclination angle to be the same as that of the inclined portion 19 a provided on the blade restricting member 19, the blade restricting member 19 is disposed so as to come into contact therewith. The blade regulating force receiving portion 41d is formed by sheet metal processing of a blade 41 made of a plate-like member.

  Then, the blade regulating force receiving portion 41d is attached so as to abut on the inclined portion 19a of the blade regulating member 19 at the broken line a portion. In the blade 41 of the modified example shown in FIG. 6, it is preferable to increase the thickness of the blade restricting member 19 in order to ensure that the blade restricting force receiving portion 41 d is brought into contact with the inclined portion 19 a of the blade restricting member 19.

  FIG. 7 is an exploded perspective view showing a fixing structure of the screw shaft of the roll paper tube holding device in the roll paper supply device according to the first embodiment. As shown in FIG. 7, the screw shaft 14, the cap 10, the torque limiter 15, and the knob 13 are disposed on the free end side of the roll paper tube holding device 4. The screw shaft 14 is provided with a threaded portion 14a at the end opposite to the free end. The knob 13 is attached by fitting the fixing protrusion 15a of the torque limiter 15 into a hole (not shown) provided inside the knob 13 in order to rotate the torque limiter 15 integrally.

  The torque limiter 15 is attached by fitting two pins 16 provided in the radial direction of the screw shaft 14 into a hole (not shown) provided therein in order to rotate the screw shaft 14 integrally. Then, the knob 13 is fixed by fitting a stopper 21 such as an O-ring into a groove portion 22 provided at the right end of the screw shaft 14 in the drawing.

  FIG. 8 is a functional block diagram of the roll paper tube holding device in the roll paper supply device according to the first embodiment. As shown in FIG. 8, the roll paper tube holding device 4 according to the first embodiment includes an axial direction moving means 100, a rotational torque limiting means 300, and a roll paper fixing means 200. The axial direction moving means 100 is for moving the blade 11 as a roll paper fixing member in the axial direction of the roll paper tube insertion shaft 9 (hereinafter referred to as “axial direction”).

  The rotational torque limiting means 300 limits the movement of the blade 11 in the axial direction by the screw shaft 14 as the axial movement means 100 within the transmission cutoff torque, that is, interrupts the transmission of torque when a load higher than the transmission cutoff torque is applied. Is to do. The roll paper fixing means 200 converts the axial movement of the blade 11 by the axial movement means 100 into a movement parallel to the axis and outward in the radial direction, and inserts the blade 11 as the roll paper fixing member into the roll paper tube. The roll paper 5 is fixed by being protruded from the outer periphery of the shaft 9 and brought into contact with substantially the entire axial direction inside the roll paper tube 5a.

  Specifically, the axial direction moving means 100 includes a screw shaft 14 provided with a threaded portion 14a at the end on the fixed end side, a knob 13 that rotates the screw shaft 14 at the end on the free end side of the screw shaft 14, The slider 17 includes a nut 18 that meshes with the threaded portion 14 a of the screw shaft 14, and moves in the axial direction as the screw shaft 14 rotates.

  The rotational torque limiting means 300 is rotated by receiving the drive of the knob 13 and transmits the rotation to the screw shaft 14 within the transmission cutoff torque, that is, the torque that cuts off the transmission of torque when a load higher than the transmission cutoff torque is applied. It consists of a limiter 15. Note that the amount of protrusion of the blade 11 changes depending on the inner diameter of each type of roll paper tube 5a. As a result, the moment when a load higher than the transmission cutoff torque is applied is different.

  Further, the roll paper fixing means 200 is movable in the radial direction in response to the movement of the slider 17 in the axial direction, and the blade that projects the blade outer end 11 c from the slit 9 s provided on the outer periphery of the roll paper tube insertion shaft 9. 11 and a blade restricting member 19 having a blade restricting force receiving portion 11a for converting the movement of the blade 11 in the axial direction into the outward movement in the radial direction.

(Description of operation)
With the above configuration, the roll paper supply device 1 according to the first embodiment operates as follows. First, the overall operation of the roll paper supply device 1 will be described with reference to FIG.
First, when print data or the like is received from a host device (not shown), a control unit (not shown) drives the transport roller 6 of the roll paper transport unit 3 and transports the belt-shaped roll paper 5b in the direction of arrow A. By this conveyance, the following belt-shaped roll paper 5b is fed out, and the roll paper 5 held rotatably on the roll paper tube holding device 4 of the roll paper holding unit 2 rotates in the direction of arrow K together with the roll paper tube holding device 4.

The fed roll-shaped roll paper 5 b is conveyed in the direction of arrow A through the roll paper conveyance unit 3 and conveyed to the printing device 25. At this time, the belt-like roll paper 5b is cut into a predetermined length by the cutter device 7. The printing device 25 prints and discharges an image on the belt-like roll paper 5b cut to a predetermined length based on the print data from the host device.
As described above, when the roll paper 5b is repeatedly fed out, printed, and cut, and the remaining amount of the roll paper 5 is reduced, a message to replace the roll paper 5 is issued, and the loading of a new roll paper 5 is prompted. Then, the roll paper 5 is exchanged.

Next, the operation of the roll paper tube holding device 4 in the roll paper supply device 1 according to the first embodiment will be described. First, the operation of the roll paper tube holding device 4 when the roll paper 5 is fixed will be described.
First, as shown in FIG. 2, when the operator rotates the knob 13 in the clockwise arrow B direction, the slider 17 is engaged by the engagement of the screw portion 14a of the screw shaft 14 and the nut 18 provided on the slider 17. Moves in the direction of arrow C as the fixed end direction. That is, since the screw portion 14a is composed of a left-hand screw, when the knob 13 is rotated in the arrow B direction, the slider 17 integrated with the nut 18 moves in the arrow C direction shown in FIG. To do. As the slider 17 moves, the blade 11 moves in the direction of arrow C through the post 11b that engages with the long hole 17a (see FIG. 5) of the slider 17.

  When the blade 11 moves in the direction of arrow C as the fixed end direction, the blade restricting force receiving portion 11a of the blade 11 contacts the inclined portion 19a of the blade restricting member 19, and the distance from the center of the roll paper tube insertion shaft 9 becomes long. That is, it rises along the inclined portion 19a. As the blade restricting force receiving portions 11a of the three blades 11 rise along the inclined portion 19a, the three blades 11 move in the direction of arrow G, that is, radially outward of the roll paper tube insertion shaft 9.

  At this time, the blade 11 moves in the G direction while being guided by the long hole 17a because the post 11b on the free end side of the blade 11 is engaged with the long hole 17a of the slide 17 as shown in FIG. As the blade 11 moves outward in the radial direction, the blade outer end 11c of the blade 11 is guided from the outer periphery of the roll paper tube insertion shaft 9 while being guided by a slit 9s as a protruding port as shown in FIG. Also protrudes outward. Similarly, the blade outer ends 11c of the other two blades 11 project outward from the outer periphery of the roll paper tube insertion shaft 9 while being guided by the slits 9s.

  Thereby, the blade outer end 11c of the blade 11 elongated in the axial direction comes into contact with the inner side of the roll paper tube 5a inserted into the roll paper tube insertion shaft 9, and the roll paper 5 can be fixed. . In particular, since the blade 11 according to the present embodiment is elongated in the axial direction of the roll paper tube insertion shaft 9, the roll paper 5 can be fixed more reliably if the length is the same as the length of the roll paper tube 5 a.

  Next, an operation for releasing the fixing of the roll paper 5 will be described. FIG. 9 is an operation explanatory diagram illustrating a roll paper fixing release operation of the roll paper tube holding device in the roll paper supply device according to the first embodiment. 9A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 9B is a YY cross-sectional view shown in FIG. 9A. In FIG. 9, the blade outer end 11c of the blade 11 protrudes from the outer periphery of the roll paper tube insertion shaft 9, and the roll paper 5 is fixed to the roll paper tube insertion shaft 9. For convenience, not shown.

  In a state where the roll paper 5 is fixed to the roll paper tube insertion shaft 9, the operator rotates the knob 13 in the arrow D direction as counterclockwise as shown in FIG. Since the screw portion 14a is composed of a left-hand screw, when the knob 13 is rotated in the arrow D direction, the nut 18 moves in the arrow E direction as the free end direction as shown in FIG. Also moves in the direction of arrow E. As the slider 17 moves, the blade 11 moves in the direction of arrow E by the post 11b that engages with the elongated hole 17a of the slider 17.

  Then, the blade restricting force receiving portion 11a of the blade 11 descends the inclined portion 19a of the blade restricting member 19, that is, the distance from the center of the roll paper tube insertion shaft 9 is shortened. The roll paper tube insertion shaft 9 moves so as to be stored inside in the radial direction. At this time, the movement of the blade 11 in the direction of arrow F is guided by the long hole 17a of the slider 17 with which the post 11b of the blade 11 is engaged. By this movement, the blade outer end 11c of the blade 11 is not brought into contact with the inside of the roll paper tube 5a inserted into the roll paper tube insertion shaft 9, and the roll paper as shown in FIG. The roll paper 5 is stored inside the outer periphery of the tube insertion shaft 9 and can be released.

  Next, the loading operation of the roll paper 5 of the roll paper tube holding device 4 in the roll paper supply device 1 according to the first embodiment will be described. FIG. 10 is an operation explanatory diagram illustrating a roll paper loading operation of the roll paper tube holding device in the roll paper supply device according to the first embodiment. 10A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 10B is a YY sectional view shown in FIG.

  When fixing the roll paper 5 to the roll paper tube insertion shaft 9, the operator fits the roll paper 5 into the roll paper tube insertion shaft 9. Further, the roll paper 5 is inserted in the direction of arrow C as the fixed end direction along the roll paper tube insertion axis 9 until it hits the flange 12-1. FIG. 10B shows a state in which only the roll paper 5 has been inserted into the roll paper tube insertion shaft 9. In this state, since the roll paper 5 is not fixed by the blade 11 of the roll paper tube insertion shaft 9, the roll paper 5 is decentered by shifting the rotation center between the roll paper tube insertion shaft 9 and the roll paper tube 5a. Indicates a state.

  Next, as shown in FIG. 10A, the knob 13 is rotated by the clockwise torque B limiter 15 until the knob 13 rotates idly. By the rotation of the knob 13 in the arrow B direction, the slider 17 moves in the arrow C direction as the fixed end direction, and the blade 11 also moves in the arrow C direction by the post 11b engaged with the long hole 17a of the slider 17.

  By the movement of the blade 11 in the arrow C direction, the blade restricting force receiving portion 11a moves up the inclined portion 19a of the blade restricting member 19, and the blade 11 moves in the arrow G direction. This movement is performed simultaneously by three blades 11, and each blade outer end 11 c protrudes outward from the slit 9 s of the roll paper tube insertion shaft 9. Then, the state shown in FIG. 11B is obtained later, and the roll paper 5 is fixed on substantially the entire surface in the axial direction inside the roll paper tube 5a by the protruding three blade outer ends 11c. That is, when the roll paper tube insertion shaft 9 and the roll paper tube 5a coincide with each other in the rotation center, the roll paper 5 is fixed by the blade 11 of the roll paper tube insertion shaft 9 and is not eccentric.

  When the knob 13 is further rotated after the inner side of the roll paper tube 5a and the blade outer end 11c are in contact with each other, torque transmission to the screw shaft 14 via the pin 16 is blocked by the torque limiter 15, and the knob 13 is idling. To do. In this state, even if a radially inward stress is applied to the blade outer end 11c, the screw shaft 14 does not rotate and the slider 17 does not move. Therefore, the blade 11 does not move radially inward due to the contact between the blade restricting force receiving portion 11a and the inclined portion 19a of the blade restricting member 19, and the roll paper 5 is securely fixed to the roll paper tube insertion shaft 9. .

  Here, when the inner diameter of the roll paper tube 5a is small, the amount of protrusion of the blade 11 is small, and the idling of the knob 13 due to the occurrence of a load greater than the transmission cutoff torque occurs early. Further, when the inner diameter of the roll paper tube 5a is large, the amount of protrusion of the blade 11 is large, and the idling of the knob 13 due to the occurrence of a load higher than the transmission cutoff torque occurs later. As described above, the amount of protrusion of the roll paper fixing member brought into contact with the inner side of the roll paper tube is changed in accordance with the inner diameter of each type of the roll paper tube. However, according to the present embodiment, the contact force between the blade 11 and the inner side of the roll paper tube 5a can be kept constant even if there is a variation in the inner diameter of each type of the roll paper tube.

  When the roll paper 5 is fixed to the roll paper tube insertion shaft 9 and is in the state shown in FIG. 11 later, the conveyance roller 6 of the roll paper conveyance unit 3 is driven, and the roll paper 5 held on the roll paper tube insertion shaft 9 The strip-shaped roll paper 5b is fed out. At this time, together with the roll paper 5, flanges 12-1, 12-2, roll paper tube insertion shaft 9, blade regulating member 19, blade 11, knob 13, screw shaft 14, torque limiter that constitute the roll paper tube holding device 4. 15 and the slider 17 and the like rotate together.

  When the roll paper 5 of the roll paper tube insertion shaft 9 is reduced, the roll paper 5 is replaced. The removal operation of the roll paper 5 of the roll paper tube holding device 4 in the roll paper supply device 1 relating to the first embodiment at this time will be described. FIG. 11 is an operation explanatory diagram illustrating a roll paper removing operation of the roll paper tube holding device in the roll paper supply device according to the first embodiment. 11A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 11B is a YY cross-sectional view shown in FIG.

  When removing the roll paper 5 from the roll paper tube insertion shaft 9, as shown in FIG. 11A, the knob 13 is rotated in the direction of the arrow D as counterclockwise, and is rotated until the roll paper 5 can be removed. . The rotation of the knob 13 in the direction of arrow D causes the slider 17 to move in the direction of arrow E as the free end direction, and the blade 11 also moves in the direction of arrow E while being guided by the post 11b that engages with the elongated hole 17a of the slider 17. Moving.

  By the movement of the blade 11 in the direction of arrow E, the blade restricting force receiving portion 11a of the blade 11 moves down the inclined portion 19a of the blade restricting member 19, and the blade 11 moves in the direction of arrow F, that is, radially inward. By this movement, the blade outer end 11 c is accommodated inside the roll paper tube insertion shaft 9. Then, the state shown in FIG. 10 (b) is obtained, and the inner fixing of the roll paper tube 5a by the blade outer end 11c is released, so that the roll paper 5 can be pulled out in the direction of arrow E as the free end direction. Become.

  When the knob 13 is further rotated in the direction of arrow D after the blade outer end 11c is separated from the inner side of the roll paper tube 5a, the slider 17 contacts the limiter 10a of the cap 10 as shown in FIG. Touch. Due to this contact, the slider 17 no longer moves in the direction opposite to the arrow C direction as the free end direction. Then, when the torque transmitted to the screw shaft 14 by the rotation of the knob 13 becomes equal to or higher than the transmission cutoff torque, the torque transmission is interrupted by the torque limiter 15 and the knob 13 rotates idly.

  As described above, according to the present embodiment, the blade 11 made of a long plate-like member parallel to the axis is moved radially outward to fix the roll paper 5, and at the same time, the blade 11 is Since the blade regulating member 19 is also provided in the axial direction in order to move outward in the radial direction, the roll paper 5 can be reliably fixed with a constant contact force, and the blade 11 is deformed based on the weight of the roll paper 5. Thus, the eccentric rotation of the roll paper 5 can be prevented.

Further, since the torque limiter 15 for limiting the movement of the blade 11 in the axial direction by the screw shaft 14 within the transmission cutoff torque is provided, the protruding amount of the blade 11 brought into contact with the inner side of the roll paper tube is equal to the inner diameter of the roll paper tube. It changes according to the size. Accordingly, it is possible to provide a roll paper supply device that can keep the contact force between the blade 11 and the inside of the roll paper tube 5a constant even if there is a variation in the inner diameter of each type of roll paper tube.
Further, the roll paper fixing operation by the knob 13 can be performed on one side as the free end side of the roll paper tube insertion shaft 9, so that the roll paper 5 can be fixed in a short time.

(Second Embodiment)
Next, the configuration of the roll paper supply device 1 according to the second embodiment will be described. Note that the overall configuration of the roll paper supply device 1 related to the second embodiment is the same as the configuration of the roll paper supply device 1 of the first embodiment shown in FIG. FIG. 12 is an explanatory diagram illustrating a configuration of a roll paper tube holding device in the roll paper supply device according to the second embodiment. 12A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 12B is a YY sectional view shown in FIG.

  As shown in FIG. 12, in the roll paper tube holding device 4 in the roll paper supply device 1 according to the second embodiment, the slider 17 in the roll paper tube holding device 4 according to the first embodiment moves toward the free end side. A spring 20 is provided instead of the limiter 10a that restricts movement. Moreover, it replaces with the torque limiter 15 in 1st Embodiment, and the socket 39 and the gear part 24 are provided. The other configuration is the same as the configuration of the roll paper tube holding device 4 according to the first embodiment, and thus the description thereof is omitted.

The gear portion 24 attached to the knob 13 is configured to mesh with a latch portion 39a of the socket 39 as shown in FIG. The socket 39 is fixed by the pin 16 of the screw shaft 14 and rotates the screw shaft 14 together. The socket 39 may be integrally formed with a resin mold such as plastic together with the latch portion 39a. Similarly, the gear portion 24 may be molded by a resin mold such as plastic.
The screw shaft 14 has a threaded portion 14 a at the end on the fixed end side, and the end on the free end side is inserted into the center holes of the cap 10, the socket 39, the gear portion 24, and the knob 13. The threaded portion 14a of the screw shaft 14 has a left-hand thread configuration similar to the roll paper tube holding device 4 relating to the first embodiment.

  In the roll paper tube holding device 4 according to the second embodiment, when the blade outer end 11c of the blade 11 is housed inside the roll paper tube insertion shaft 9, the screw portion 14a of the screw shaft 14 is fixed. The length of the screw shaft 14 is formed long so that it is offset toward the end side and does not mesh with the nut 18 of the slider 17. Details of this will be described later. The compression spring 20 is disposed between the cap 10 and the slider 17 and always urges the slider 17 in the direction of arrow C as the fixed end direction.

  A configuration around the socket 39 of the roll paper tube holding device 4 according to the second embodiment will be described in detail. FIG. 13 is an exploded perspective view around the socket of the roll paper tube holding device in the roll paper supply device according to the second embodiment. FIG. 14 is a cross-sectional view taken along line HH shown in FIG. 12B in the roll paper tube holding device 4.

  As shown in FIG. 13, in the roll paper tube holding device 4 according to the second embodiment, the gear portion 24 is provided with a fixed protrusion 24 a inside the knob 13 so as to rotate integrally with the knob 13. Fit in a hole not shown. The gear portion 24 may be formed together with the knob 13 by integral molding. As shown in FIG. 14, the socket 39 is attached so that the latch portion 39 a provided on the inner periphery of the socket 39 and the gear portion 24 come into contact with each other.

  Further, the socket 39 is fixed by a pin 16 so that the screw shaft 14 is rotated integrally. Then, the screw shaft 14 is passed through the center holes of the cap 10, the socket 39, the gear portion 24, and the knob 13, and the stopper 21 is fitted and fixed to the groove portion 22 provided at the end portion on the free end side of the screw shaft 14.

  With such a configuration, in the roll paper tube holding device 4 according to the second embodiment, when the roll paper 5 is fixed to the roll paper tube insertion shaft 9, the friction force between the latch portion 39 a and the gear portion 24 is used. Torque due to rotation of the knob 13 (gear portion 24) in the direction of arrow B is transmitted to the screw shaft 14. Further, when the latch portion 39a gets over the teeth of the gear portion 24, a collision sound is generated in which the latch portion 39a re-contacts the gear portion 24. The collision sound can notify the operator that the roll paper 5 has been fixed.

  FIG. 15 is a functional block diagram of the roll paper tube holding device in the roll paper supply device according to the second embodiment. As shown in FIG. 15, the roll paper tube holding device 4 according to the second embodiment has the roll paper 5 fixed in addition to the axial movement means 100, the roll paper fixing means 200, and the rotational torque limiting means 300. Is provided with a roll paper fixing notifying unit 400 for notifying the user.

  In the roll paper supply device 1 according to the second embodiment, the rotational torque limiting means 300 includes a gear portion 24 attached to the knob 13 and a socket 39 provided with a latch portion 39a that abuts against the gear portion 24. Become. The roll paper fixing notification means 400 indicates that the blade outer end 11c of the blade 11 has come into contact with the inner side of the roll paper tube 5a due to the collision sound generated when the teeth of the latch portion 39a and the gear portion 24 come into contact again. This is to notify that the paper 5 is fixed.

(Description of operation)
With the above configuration, the roll paper supply device 1 and the roll paper tube holding device 4 according to the second embodiment operate as follows. The overall operation of the roll paper supply device 1 related to the second embodiment is the same as the operation of the roll paper supply device 1 related to the first embodiment, and a description thereof will be omitted.
First, the operation of the knob 13 and the socket 39 of the roll paper supply device 1 according to the second embodiment will be described with reference to FIG. First, when the operator rotates the knob 13 in the direction of arrow B shown in FIG. 12 (a) as clockwise, the gear portion 24 attached to the knob 13 is also in the direction of arrow B shown in FIG. 14 as clockwise. Rotate to. Then, the socket 39 rotates in the arrow B by the frictional force of the gear portion 24 and the latch portion 39a of the socket 39.

  When the knob 13 is further rotated in the direction of arrow B and a load greater than the frictional force between the gear portion 24 and the latch portion 39a is applied to the socket 39, the latch portion 39a gets over the teeth of the gear portion 24 and the socket 39 rotates. Is suppressed, and the knob 13 idles. At this time, the latch portion 39a bends once while getting over the teeth of the gear portion 24, and makes a collision sound when it gets over the teeth of the gear portion 24 and re-contacts with the gear portion 24.

  On the other hand, when the knob 13 is rotated counterclockwise in the direction of arrow D, the tip of the latch portion 39a of the socket 39 comes into contact with the gear portion 24 attached to the knob 13. In this case, both the knob 13 and the socket 39 rotate in the direction of arrow D as counterclockwise. At this time, no collision sound is generated.

  Next, the loading operation of the roll paper 5 of the roll paper tube holding device 4 according to the second embodiment will be described. FIG. 16 is an operation explanatory diagram illustrating a roll paper loading operation of the roll paper tube holding device in the roll paper supply device according to the second embodiment. 16A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 16B is a YY sectional view shown in FIG.

  When the roll paper 5 is fixed to the roll paper tube insertion shaft 9, the roll paper 5 is fitted into the roll paper tube insertion shaft 9 in the same manner as the roll paper tube holding device 4 according to the first embodiment. That is, the roll paper 5 is inserted in the arrow C direction as the fixed end direction along the roll paper tube insertion axis 9 until it hits the flange 12-1. FIG. 16B shows a state in which only the roll paper 5 has been inserted into the roll paper tube insertion shaft 9. This state is an eccentric state because the roll paper 5 is not fixed by the blade 11 of the roll paper tube insertion shaft 9 as shown in FIG.

Next, the operator rotates the knob 13 in the direction of arrow B as clockwise, and the knob 13 until the collision sound starts when the latch portion 39a gets over the teeth of the gear portion 24 and comes into contact with the gear portion 24 again. Rotate.
That is, as the knob 13 rotates in the direction of arrow B, the slider 17 moves in the direction of arrow C as the fixed end direction. By this movement, the blade 11 is also moved in the direction of arrow C by the post 11b engaged with the long hole 17a of the slider 17.

  By the movement of the blade 11 in the arrow C direction, the blade restricting force receiving portion 11a rises up the inclined portion 19a of the blade restricting member 19, and the blade 11 moves in the arrow G direction as the radially outer side of the roll paper tube insertion shaft 9. . Then, the blade outer end 11c protrudes outward from the slit 9s shown in FIG. Then, the state shown in FIG. 17B is obtained later, and the inner side of the roll paper tube 5a is fixed by the protruding blade outer end 11c, and the roll paper 5 is fixed to the roll paper tube insertion shaft 9. In other words, the roll paper 5 is fixed by the blade 11 of the roll paper tube insertion shaft 9 and is not in an eccentric state.

  When the knob 13 is further rotated after the inner side of the roll paper tube 5a and the blade outer end 11c are in contact with each other, a load greater than the frictional force between the gear portion 24 and the latch portion 39a is applied to the socket 39. And the latch part 39a gets over the tooth | gear of the gear part 24, and it will be in the state which the knob 13 idles without the socket 39 rotating. That is, the transmission of torque to the screw shaft 14 via the socket 39 due to the rotation of the knob 13 is interrupted, and the knob 13 is idled. At this time, a collision sound is generated when the latch portion 39a of the socket 39 gets over the teeth of the gear portion 24 and re-contacts the gear portion 24. Due to the occurrence of the collision sound, the operator can know that the roll paper 5 is fixed to the roll paper tube insertion shaft 9 and stops the rotation of the knob 13.

  When the roll paper 5 is fixed to the roll paper tube insertion shaft 9 and the state shown in FIG. 17 is reached, the transport roller 6 of the roll paper transport unit 3 is driven, and the roll paper 5 held by the roll paper holding unit 2 is fed out. . At this time, the flanges 12-1 and 12-2, the blade regulating member 19, the blade 11, the knob 13, the screw shaft 14, the socket 39, the slider 17 and the like rotate together with the roll paper 5. Thereby, the belt-like roll paper 5b of the roll paper 5 is fed out.

  When the roll paper 5 of the roll paper tube insertion shaft 9 is reduced, the roll paper 5 is replaced. The operation of removing the roll paper 5 of the roll paper tube holding device 4 relating to the second embodiment will be described. FIG. 17 is an operation explanatory diagram illustrating a roll paper removing operation of the roll paper tube holding device in the roll paper supply device according to the second embodiment. 17A is a front view seen from the direction of the arrow X shown in FIG. 1, and FIG. 17B is a YY sectional view shown in FIG.

  When the roll paper 5 is removed from the roll paper tube insertion shaft 9, as shown in FIG. 17A, the operator can rotate the knob 13 in the direction of arrow D counterclockwise to remove the roll paper 5. Rotate until That is, the rotation of the knob 13 in the direction of arrow D causes the slider 17 to move in the direction of arrow E as the free end direction, and the blade 11 also moves in the direction of arrow E by the post 11b engaged with the long hole 17a of the slider 17. To do.

  As the blade 11 moves in the direction of arrow E, the blade restricting force receiving portion 11a moves down the inclined portion 19a of the blade restricting member 19, and the blade 11 moves in the direction of arrow F as the radially inner side. By this movement, the blade outer end 11 c is accommodated inside the roll paper tube insertion shaft 9. Then, the inner side of the roll paper tube 5a by the blade outer end 11c is released, so that the operator can pull out the roll paper 5 in the direction of arrow E.

  When the knob 13 is further rotated in the direction of arrow D after the inner side of the roll paper tube 5a is separated from the blade outer end 11c, the screw portion 14a of the screw shaft 14 and the nut 18 are disengaged (FIG. 16). (See (b)), the slider 17 does not move in the direction of arrow E as the free end direction any more. Even if the screw portion 14a and the nut 18 are disengaged, the slider 17 is urged in the direction of arrow C by the compression spring 20, so that the knob 13 is rotated again in the direction of arrow B. The threaded portion 14a and the nut 18 are engaged with each other.

  As described above, according to the roll paper tube holding device 4 relating to the second embodiment, the roll paper fixing notifying means for notifying the fixation of the roll paper 5 by the collision sound of the re-contact between the latch portion 39a and the gear portion 24. Since 400 is provided, in addition to the effects described in the roll paper supply device 1 related to the first embodiment, it is possible to notify the fixation of the roll paper 5 by a collision sound, and it is possible to more reliably fix the roll paper 5. it can.

(Modification 1 of embodiment)
In the description of the roll paper tube holding device 4 relating to the second embodiment described above, when a load more than the frictional force between the gear portion attached to the knob 13 and the latch portion 39a of the socket 39 is applied to the socket 39, the knob Although the configuration for interrupting the transmission of torque due to the rotation of 13 has been described as an example, the configuration may be as follows. That is, a torque limiter 15 is further provided in the configuration of the roll paper tube holding device 4 relating to the second embodiment, and the transmission cutoff torque of the torque limiter 15 is made larger than the frictional force between the gear portion 24 and the latch portion 39a. is there.

  FIG. 18 is an explanatory diagram illustrating a configuration around the socket of the roll paper tube holding device in the roll paper supply device according to Modification 1 of the second embodiment. 18A is an exploded perspective view of the periphery of the socket related to the first modification of the second embodiment, and FIG. 18B is a front view of the periphery of the socket related to the first modification and a YY sectional view thereof. is there.

In the first modification of the second embodiment, the torque limiter 15 is disposed between the knob 13 and the gear portion 24 as shown in FIG. The screw shaft 14 is provided with a first pin 56a for fixing the socket 39 and a second pin 56b for fixing the torque limiter 15. Then, the screw shaft 14 is passed through the cap 10, the socket 39, the gear portion 24, the torque limiter 15, and the center hole of the knob 13 and fixed with the stopper 21.
When assembled in this manner, as shown in FIG. 18B, the socket 39 is fixed to the screw shaft 14 by the first pin 56a, and the torque limiter 15 is fixed by the second pin 56b. Moreover, the gear part 24 is attached so that it may contact | abut with the latch part 39a of the socket 39 similarly to FIG. 14 of above-mentioned 2nd Embodiment.

  Here, when the roll paper 5 is fixed to the roll paper tube insertion shaft 9, as shown in FIG. 18B, the knob 13 is rotated in the arrow B direction as clockwise. Then, the torque generated by the rotation of the knob 13 is transmitted to the screw shaft 14 via the second pin 56b that fixes the torque limiter 15, and the screw shaft 14 rotates in the arrow B direction. As the screw shaft 14 rotates, the screw portion 14a rotates in the arrow B direction, and the slider 17 moves in the arrow C direction as the fixed end direction.

  By the movement of the slider 17 in the direction of arrow C, the blade outer end 11c of the blade 11 abuts on the inner side of the roll paper tube 5a and the roll paper 5 is inserted into the roll paper tube as in the description of the second embodiment. It is fixed to the shaft 9. At this time, the socket 39 is also rotated with the rotation of the knob 13 by the first pin 56a. Accordingly, since the gear portion 24 provided on the knob 13 and the latch portion 39a of the socket 39 rotate together, the latch portion 39a does not exceed the teeth of the gear portion 24, and no collision noise is generated when re-contacting.

  Further, when the knob 13 continues to rotate clockwise in the direction of the arrow B, and the blade outer end 11c of the blade 11 contacts the inner side of the roll paper tube 5a, the screw shaft 14 exceeds the transmission cutoff torque of the torque limiter 15. Load. Then, the screw shaft 14 does not rotate even if the knob 13 is further rotated in the arrow B direction due to the torque transmission blocking action of the torque limiter 15. At this time, the gear portion 24 provided on the knob 13 rotates in the direction of arrow B, but the socket 39 does not rotate. Therefore, when the latch portion 39a gets over the teeth of the gear portion 24 and re-contacts the teeth of the gear portion 24, A collision sound is emitted. That is, the latch portion 39 a of the socket 39 emits a collision sound that informs the fixation of the roll paper 5.

  On the other hand, when the roll paper 5 is removed from the roll paper tube insertion shaft 9, the knob 13 is rotated counterclockwise in the direction of arrow D as shown in FIG. Then, the gear part 24 attached to the knob 13 rotates in the direction of arrow D, and comes into contact with the teeth of the gear part 24 so that the tip of the latch part 39a of the socket 39 bites. Therefore, both the knob 13 and the socket 39 rotate in the direction of the arrow D, and the screw shaft 14 rotates in the direction of the arrow D by the first pin 56 a that fixes the socket 39. At this time, no collision sound is generated. As the screw shaft 14 rotates, the screw portion 14a rotates in the direction of arrow D, and the slider 17 moves in the direction of arrow E as the free end direction. By the movement of the slider 17, the blade outer end 11c of the blade 11 is separated from the inside of the roll paper tube 5a, and the roll paper 5 can be removed.

  When the knob 13 continues to rotate in the arrow D direction, the screw shaft 14 continues to rotate in the arrow D direction, and the slider 17 further moves in the arrow E direction. And if it remove | deviates from the screw part 14a from the nut 18 of the slider 17, the screw shaft 14 will come to idle.

  As described above, in the modification of the second embodiment, the torque limiter 15 is added to the configuration of the second embodiment, the socket 39 is fixed by the first pin 56a, and the torque limiter 15 is While being fixed by the pin 56b, the transmission cutoff torque of the torque limiter 15 was made larger than the frictional force between the gear portion 24 and the latch portion 39a. Accordingly, the socket 39 has only a roll paper fixing notification function for generating a collision sound that notifies the fixing of the roll paper 5, and the torque limiter 15 can perform the function of limiting the rotational torque.

(Modification 2 of embodiment)
In the description of the roll paper tube holding device 4 relating to the above embodiment, the three blades 11 are provided inside the roll paper tube insertion shaft 9, but two may be provided. It is good also as a structure which provides 4 or more.

(Modification 3 of embodiment)
Further, in the description of the roll paper tube holding device 4 in the roll paper supply device 1 relating to the above embodiment, it has been described that the operator rotates the knob 13, but the sensor and knob for detecting the replacement time of the roll paper 5 are described. It is also possible to provide a drive means for rotationally driving 13, detect the replacement time of the roll paper 5 by the sensor, and rotate the knob 13 by the drive means.

(Modification 4 of embodiment)
Further, in the description of the roll paper tube holding device 4 in the roll paper supply device 1 relating to the above embodiment, it has been described that the inclined portion 19a of the blade regulating member 19 and the blade regulating force receiving portion 11a are provided in two places, Each may be provided in one place, or may be provided in three or more places.

DESCRIPTION OF SYMBOLS 1 Roll paper supply apparatus 2 Roll paper holding part 3 Roll paper conveyance part 4 Roll paper pipe holding apparatus 5 Roll paper 9 Roll paper pipe insertion shaft 19 Blade regulation member 19a Inclination part 11 Blade 11a Blade regulation force receiving part 13 Knob 14 Screw shaft 15 Torque limiter 17 Slider 39 Socket 39a Latch part 24 Gear part 100 Axial moving means 200 Roll paper fixing means 300 Rotating torque limiting means 400 Roll paper fixing notifying means

Claims (12)

A roll paper supply device that holds roll paper and supplies it to other devices,
A roll paper insertion shaft that is a hollow cylindrical shape and rotatably holds the roll paper on a cylindrical outer periphery;
A roll paper fixing member which is housed inside the roll paper insertion shaft, is formed of a long plate-like member parallel to the axis of the roll paper insertion shaft, and is provided so as to protrude from the outer periphery of the roll paper insertion shaft;
An axial movement means that is housed inside the roll paper insertion shaft, is provided so as to be movable in the axial direction of the roll paper insertion shaft, and moves the roll paper fixing member radially outward by movement in the axial direction;
Provided at one end of the roll paper insertion shaft in the axial direction, and provided with an operation unit for moving the axial movement means in the axial direction,
The roll paper fixing member moves outward in the radial direction of the roll paper insertion shaft and protrudes from the outer periphery of the roll paper insertion shaft according to the axial movement of the axial movement means by operation of the operation unit, A roll paper supply device for fixing roll paper. On the outer periphery of the roll paper insertion shaft, provided with a slit-like projecting opening parallel to the axis and long in the width direction of the roll paper,
The roll paper fixing member can project from the projecting port by disposing one side end of the long shape toward a radially outer side of the roll paper insertion shaft, and the one side end of the long shape can be projected to the roll. The roll paper supply device according to claim 1, wherein the roll paper supply device can be brought into contact with paper.   The roll paper supply device according to claim 2, wherein a plurality of the protrusions are provided at equal intervals on an outer periphery of the roll paper insertion shaft, and a plurality of the roll paper fixing members are provided corresponding to the protrusions. . The roll paper fixing member includes a plurality of regulating force receiving portions radially inside,
And a regulating member that is housed inside the roll paper insertion shaft and has an inclined portion that comes into contact with the regulating force receiving portion,
In accordance with the movement of the axial movement means in the axial direction, the roll paper fixing member is moved in parallel with the roll paper insertion axis and radially outward by the contact between the inclined portion and the restriction force receiving portion. The roll paper supply device according to claim 1, characterized in that: The axial direction moving means includes a screw shaft provided with a threaded portion at one end, and a slider that moves in the axial direction with a nut meshing with the threaded portion,
The operation unit includes a knob that rotates the screw shaft at the other end of the screw shaft.
2. The roll paper according to claim 1, wherein when the roll paper is fixed, the screw shaft is rotated by rotation of the knob in a predetermined direction, and the slider is moved in a predetermined direction by rotation of the screw shaft. Feeding device.   2. The roll paper supply device according to claim 1, further comprising a rotational torque limiting means for limiting the movement in the axial direction by the axial movement means within a transmission cutoff torque.   The roll paper supply device according to claim 6, wherein the rotational torque limiting unit includes a torque limiter that rotates integrally with the operation unit. The rotational torque limiting means includes a gear portion attached to the operation portion, and a latch portion to be brought into contact with the gear portion,
7. The roll paper supply device according to claim 6, wherein when the roll paper is fixed, torque due to rotation of the knob is transmitted to the axial movement means by frictional force between the gear portion and the latch portion. .   9. The roll paper fixing notifying means for notifying the fixing of the roll paper by a collision sound between the gear part and the latch part when a predetermined load is generated in the axial direction moving means. Roll paper supply device.   When removing the roll paper, the screw shaft is rotated by rotating the knob in a direction opposite to the predetermined direction, thereby moving the slider in the reverse direction of the predetermined direction, and the screw portion of the screw shaft. The roll paper supply device according to claim 5, wherein the slider is disengaged from the nut.   When the screw portion of the screw shaft and the nut of the slider are disengaged, the slider is urged toward the screw portion, and the slider and the screw portion can be engaged again. The roll paper supply device according to claim 10, further comprising an urging unit. The roll paper supply device according to claim 8 or 9, further comprising a torque limiter having a transmission cutoff torque larger than a frictional force between the gear portion and the latch portion.

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