The present invention relates to a winding apparatus for winding a continuous medium and a printing apparatus.
Winding apparatuses for winding a continuous medium around a paper tube that is attached to a winding core section are known, for example, in JP-A-2015-134686.
The winding apparatus disclosed in JP-A-2015-134686 can also directly wind a continuous medium around the winding core section without the paper tube. Without the paper tube, however, it is not easy to remove the continuous medium that has been wound around the winding core section from the winding core section.
An advantage of some aspects of the invention is to provide a winding apparatus that enables users to readily remove a continuous medium from a winding core section and a printing apparatus.
According to an aspect of the invention, a winding apparatus includes a winding core unit onto which a continuous medium is to be wound, the winding core unit having a notched portion having a shape in which a part of the winding core unit in a circumferential direction is cut out as viewed in an extending direction of the winding core unit, and a notch complementing unit to be detachably inserted into the notched portion from one end portion side in the extending direction of the winding core unit, the notch complementing unit being configured to complement the notched portion.
According to another aspect of the invention, a printing apparatus includes a printing unit configured to perform printing onto a continuous medium, a winding core unit onto which the continuous medium is to be wound, the winding core unit having a notched portion having a shape in which a part of the winding core unit in a circumferential direction is cut out as viewed in an extending direction of the winding core unit, and a notch complementing unit to be detachably inserted into the notched portion from one end portion side in the extending direction of the winding core unit, the notch complementing unit being configured to complement the notched portion.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, an embodiment of a printing system that includes a tape printing apparatus and a winding apparatus will be described with reference to the attached drawings. To clarify an arrangement relationship of components, in the drawings described below, the XYZ coordinate system is provided, however, it should be understood that the system does not limit the invention. The numerical values indicating the number of components or the like are merely examples, and do not limit the invention.
With reference to
The tape printing apparatus 101 includes an apparatus case 103 and an attachment section cover 105. The apparatus case 103 is a substantially rectangular parallelepiped. The apparatus case 103 has a tape introduction port 107 on the +X side and a tape discharge port 109 on the −X side. Into the tape introduction port 107, the tape 401 is introduced from the outside of the tape printing apparatus 101. The printed tape 401 is discharged from the tape discharge port 109. A cartridge attachment section that is not illustrated is provided on the +Z side of the apparatus case 103. The attachment section cover 105 is provided on the +Z side of the apparatus case 103 so as to be pivotable about an end portion on the +Y side. The attachment section cover 105 is used to open or close the cartridge attachment section. To the cartridge attachment section, a ribbon cartridge that is not illustrated that accommodates an ink ribbon is detachably attached.
Although not illustrated, in the apparatus case 103, a platen shaft, a thermal head, and a feed motor are provided. To the platen shaft, a platen roller is rotatably attached. When the feed motor is started, the platen roller rotates and the tape 401 and the ink ribbon held between the thermal head and the platen roller are sent. Then, the thermal head generates heat, and printing is performed onto the tape 401.
The winding apparatus 201 is disposed on the tape discharge port 109 side of the tape printing apparatus 101. The winding apparatus 201 includes a base section 203, a winding section 205, and a winding guide section 207.
The base section 203 is smaller in the Z direction than the apparatus case 103 of the tape printing apparatus 101 and has a substantially rectangular parallelepiped shape. On a surface on the +Z side of the base section 203, a dial 208 is rotatably provided. The user operates the dial 208 to adjust a position of the winding section 205 in the Z direction.
Onto the winding section 205, the tape 401 that has been sent from the tape printing apparatus 101 is wound. The winding section 205 includes a winding body 209 and a winding attachment body 211. The winding body 209 is rotatably provided on the surface on the +Z side of the base section 203. The winding attachment body 211 is detachably attached to the winding body 209 and rotates together with the winding body 209.
The winding body 209 includes a winding core section 213, see
The winding guide section 207 is provided on the surface on the +Z side of the base section 203. The winding guide section 207 guides the tape 401 that is sent from the tape discharge port 109 of the tape printing apparatus 101 to the winding section 205. The winding guide section 207 includes a first guide roller 221, a friction member 223, a second guide roller 225, and a guide wall 226. The first guide roller 221 guides the tape 401 that is sent from the tape discharge port 109 to the friction member 223. The friction member 223 applies frictional resistance to the tape 401 such that the force to pull the tape 401 toward the winding section 205 is reduced. The second guide roller 225 guides the tape 401 that is sent from the friction member 223 to the winding section 205. The guide wall 226 suppresses the slack in the tape 401 toward the winding section 205 side while the tape 401 is sent from the first guide roller 221 to the friction member 223.
With reference to
With reference to
The winding core section 213 has a substantially cylindrical shape and extends in the Z direction. The winding core section 213 has a rod insertion section 227, a notched section 229, a tape insertion section 231, and two engagement-section formed surfaces 233.
The rod insertion section 227 is provided at a substantially central portion in the winding core section 213 as viewed from the +Z side. The rod insertion section 227 is a space extending along the extending direction of the winding core section 213 and has a shape in which a part of a circle is linearly cut away as viewed from the +Z direction. When the winding attachment body 211 is attached to the winding body 209, into the rod insertion section 227, a rod section 255, see
The notched section 229 is a space extending along the extending direction of the winding core section 213 and has a shape in which a part of the winding core section 213 in the circumferential direction is cut out in a substantially fan shape as viewed from the +Z direction. The notched section 229 is continuous with the rod insertion section 227 on a radially inner side as viewed from the +Z side. When the winding attachment body 211 is attached to the winding body 209, into the notched section 229, a notch complementing section 249, see
The tape insertion section 231 is provided on the side opposite to the notched section 229 with respect to the rod insertion section 227 as viewed from the +Z side. The tape insertion section 231 is a space extending along the extending direction of the winding core section 213, and has a substantially rectangular shape as viewed from the +Z direction. On a circumferential surface of the winding core section 213, a slit-like tape insertion opening 235 that extends in the extending direction of the winding core section 213 is provided. The tape insertion opening 235 is continuous with one end portion of the tape insertion section 231 in a longitudinal direction as viewed from the +Z side. Hereinafter, the longitudinal direction of the tape insertion section 231 as viewed from the +Z side is simply referred to as “longitudinal direction of the tape insertion section 231”, and a short side direction of the tape insertion section 231 as viewed from the +Z side is simply referred to as “short side direction of the tape insertion section 231”.
Before winding the tape 401, the beginning of the tape 401 to be wound around the winding core section 213 is inserted into the tape insertion section 231 from the tape insertion opening 235 by the user. When the winding attachment body 211 is attached to the winding body 209, into the tape insertion section 231, a tape holding protrusion 271, see
The two engagement-section formed surfaces 233 are positioned so as to be substantially symmetric with respect to points with the center of the winding core section 213 as the center of symmetry as viewed from the +Z side. In other words, each engagement-section formed surface 233 is provided between the notched section 229 and the tape insertion opening 235 in the circumferential direction of the winding core section 213 as viewed from the +Z side.
On each engagement-section formed surface 233, five core-side engagement sections 237 are provided along the extending direction of the winding core section 213. The five core-side engagement sections 237 are provided so as to correspond to the five tapes 401 having the widths from 12 mm to 50 mm. The core-side engagement section 237 is engaged with a lever-side engagement section 279, see
The first flange section 215 is provided on an end portion of the winding core section 213 on the −Z side. The first flange section 215 and the winding core section 213 are integrally formed. At a central portion of the first flange section 215, a shaft insertion hole 239 is provided. In the shaft insertion hole 239, a winding shaft 241 that extends along the extending direction of the winding core section 213 is inserted. The winding body 209 is supported by the winding shaft 241 so as to be rotatable and movable in the extending direction of the winding shaft 241. The winding shaft 241 that is inserted in the shaft insertion hole 239 positions the first flange section 215 in a direction intersecting the extending direction of the winding shaft 241, that is, in the X direction and the Y direction. The winding shaft 241 is fixed to a winding-side support plate that is provided in the base section 203 and protrudes from the winding-side support plate toward the +Z side.
The first flange section 215 has a non-gear portion 243 on the +Z side and a flange gear portion 245 on the −Z side. The flange gear portion 245 meshes with an output gear that is not illustrated. To the output gear, the power of the feed motor in the tape printing apparatus 101 is transmitted. In other words, the winding section 205 is rotated by the feed motor as a drive source. Alternatively, the winding section 205 may be rotated by a motor in the winding apparatus 201 as a drive source.
Winding Attachment Body
With reference to
The rod forming body 247 includes a rod section 255 and a complementary attachment section 257, see
The notch complementing section 249 has a substantially fan columnar shape that extends in the extending direction of the winding core section 213. Specifically, the notch complementing section 249 has a substantially fan shape similar to the shape of the notched section 229 as viewed from the +Z side, see
A complementary shaft section 259, see
To the complementary attachment section 257, a complementary spring that is not illustrated for applying a force to the notch complementing section 249 toward the contact position is provided. The complementary spring prevents the notch complementing section 249 from freely moving while the winding attachment body 211 is detached from the winding body 209. The complementary spring may be, for example, a compression coil spring.
The notch complementing section 249 has, on an inner side, a complementary convex portion 261 on the −Z side and a complementary concave portion 263 on the +Z side. The complementary convex portion 261 protrudes more than the complementary concave portion 263 on the inner side of the notch complementing section 249. The complementary convex portion 261 is continuous with the complementary concave portion 263 via an oblique complementary step portion 265.
The flange forming body 251 has a cylindrical section 267 and the second flange section 219 that is provided on a −Z side end portion of the cylindrical section 267. The cylindrical section 267 has a substantially cylindrical shape in which the +Z side is closed. Into the cylindrical section 267, the rod forming body 247 is inserted from the −Z side such that the +Z side of the rod forming body 247 is slidably held with respect to the cylindrical section 267. In other words, the flange forming body 251 can move in the extending direction of the winding core section 213 with respect to the rod forming body 247.
From the inner surface of a wall section of the cylindrical section 267 on the +Z side, a rod covering portion 269 and a tape holding protrusion 271 protrude toward the −Z side. The rod covering portion 269 covers the outer circumferential surface of the +Z side end portion of the rod section 255. On a −Z side end portion of the rod covering portion 269, a switching regulating section 273 is provided. The switching regulating section 273, which will be described in detail below, regulates the notch complementing section 249 so as not to be switched from the contact position to the separated position. The tape holding protrusion 271 is inserted into the tape insertion section 231 in the winding body 209 from the +Z side when the winding attachment body 211 is attached to the winding body 209.
On the outer circumferential surfaces of the cylindrical section 267, two lever supporting sections 275 are provided. The two lever supporting sections 275 are disposed to correspond to the two engagement-section formed surfaces 233, which are provided on the winding core section 213. The lever supporting sections 275 pivotably supports the levers 253 respectively.
Each of the levers 253 is pivotably supported by the lever supporting section 275 around a substantially middle position in the extending direction of the winding core section 213. On a +Z side end portion of the lever 253, a finger placing section 277 is provided and on an inner side of a −Z side end portion of the lever 253, the lever-side engagement section 279, see
It is noted that a flange-lifting spring that is not illustrated is provided between the rod section 255 and the cylindrical section 267. The flange-lifting spring may be, for example, a compression coil spring. The flange-lifting spring applies a force to the rod forming body 247 and the flange forming body 251 in directions to separate from each other along the extending direction of the winding core section 213. Accordingly, even if the user releases the levers 253 at positions where the flange forming body 251 has been moved to the −Z side from the positions at which the lever-side engagement sections 279 engage with the core-side engagement sections 237, by the flange-lifting spring, the flange forming body 251 can be moved to the +Z side to the positions lever-side engagement sections 279 engage with the core-side engagement sections 237. With this structure, the tape 401 is prevented from being deformed in the width direction.
With reference to
The switching regulating section 273, which is provided in the flange forming body 251, is located in a position corresponding to the complementary concave portion 263 of the notch complementing section 249 in the extending direction of the winding core section 213. Consequently, the notch complementing section 249 is allowed to be switched from the contact position to the separated position.
As described above, while the second flange section 219 is in the guide position, the notch complementing section 249 is regulated so as not to be switched to the separated position. Accordingly, even if the winding force of the tape 401 that has been wound around the winding core section 213 acts on the notch complementing section 249, the notch complementing section 249 is not switched from the contact position to the separated position and remains in the contact position. Consequently, during the winding operation, the circular shape of the circumferential surface of the winding core section 213 can be maintained by the notch complementing section 249, thereby winding can be stably performed.
As described above, while the second flange section 219 is in the non-guide position, the notch complementing section 249 is allowed to be switched to the separated position. Accordingly, if the winding force of the tape 401 wound around the winding core section 213 acts on the notch complementing section 249, the notch complementing section 249 is moved from the contact position to the separated position. Consequently, after the completion of winding operation, a space is formed between the tape 401 that has been wound around the winding core section 213 and the notch complementing section 249, and the winding attachment body 211 can be readily removed from the winding body 209. It is noted that when the notch complementing section 249 is moved to the separated position, the complementary concave portion 263 may be in contact with the switching regulating section 273 or may not be in contact with the switching regulating section 273.
After the winding attachment body 211 is detached from the winding body 209, the notch complementing section 249 is pulled out from the notched section 229, and the notched section 229 is exposed. Accordingly, the user can put fingers into the notched section 229 and hold the tape 401 that has been wound around the winding core section 213, and can readily remove the tape 401 from the winding core section 213. Although the winding of the widest tape 401 has been described, the same applies to winding of the tapes 401 of other widths.
With reference to
The tape receiving section 281 has a receiving wall section 285 that is provided on the tape holding section 283 side. The receiving wall section 285 extends in the extending direction of the winding core section 213. A receiving member 287 is fixed to a surface of the receiving wall section 285 on the tape holding section 283 side. It is preferable that the receiving member 287 be made of a material having a high coefficient of friction such as silicone rubber. Instead of the receiving wall section 285, the receiving member 287 may be provided on a pressure wall section 291 of the tape holding section 283, which will be described below, or may be provided on both the receiving wall section 285 and the pressure wall section 291. A spring attachment boss 289 protrudes from a surface of the receiving wall section 285 on the opposite side of the tape holding section 283 side. To the spring attachment boss 289, a tape receiving spring is attached. The tape receiving spring is provided between the receiving wall section 285 and the winding core section 213 and applies force to the tape receiving section 281 toward the tape holding section 283 side. The tape receiving section 281 is an example “medium receiving unit” according to the invention.
The tape holding section 283 has a substantially right triangular prism shape with an open surface on the opposite side of the tape receiving section 281 side as viewed in the short side direction of the tape insertion section 231. The tape holding section 283 has the pressure wall section 291 that is provided on the tape receiving section 281 side. On an end portion of the tape holding section 283 on the −Z side and on the tape receiving section 281 side, a holding shaft section 293 is provided. The holding shaft section 293 is located on the −Z side of the receiving wall section 285 and extends in the short side direction of the tape receiving section 281. The tape holding section 283 is attached to the winding body 209 so as to be able to pivot about the holding shaft section 293. Specifically, the pressure wall section 291 of the tape holding section 283 is substantially parallel to the extending direction of the winding core section 213. The tape holding section 283 can pivot between a holding position, see
The tape holding protrusion 271 that is inserted into the tape insertion section 231 from the +Z side is inserted into the tape insertion section 231 from the +Z side as described above when the winding attachment body 211 is attached to the winding body 209. The tape holding protrusion 271 is pulled out from the tape insertion section 231 toward the +Z side when the winding attachment body 211 is detached from the winding body 209. An end portion of the tape holding protrusion 271 has an oblique shape in which the tape holding section 283 side is the −Z side and the tape receiving section 281 side is the +Z side. The tape holding protrusion 271 is an example “holding operation unit” according to the invention.
As described above, when the winding attachment body 211 is attached to the winding body 209, that is, when the second flange section 219 is attached to the winding core section 213, the tape holding section 283 is moved to the holding position, fixing the end portion of the tape 401 to the winding core section 213. Accordingly, the end portion of the tape 401 can be fixed to the winding core section 213 before starting winding without using an adhesive tape, or the like.
As described above, when the winding attachment body 211 is detached from the winding body 209, that is, when the second flange section 219 is detached from the winding core section 213, the tape holding section 283 is switched to the non-holding position, releasing the fixing of the end portion of the tape 401 to the winding core section 213. Accordingly, after the completion of winding, the tape 401 that has been wound around the winding core section 213 can be readily removed from the winding core section 213.
As described above, the winding apparatus 201 according to the embodiment includes the winding core section 213 and the notch complementing section 249. Onto the winding core section 213, the tape 401 is wound. The winding core section 213 has the notched section 229 having the shape in which a part of the winding core section 213 in the circumferential direction is cut out as viewed in the extending direction of the winding core section 213. The notch complementing section 249 is detacheably inserted into the notched section 229 from the +Z side to complement the notched section 229.
With this structure, during the winding operation, the circular shape of the circumferential surface of the winding core section 213 can be maintained by the notch complementing section 249, thereby winding can be stably performed. Furthermore, after the completion of winding, by pulling out the notch complementing section 249 from the notched section 229, the user can put fingers into the notched section 229 and hold the tape 401 that has been wound around the winding core section 213. Accordingly, the user can readily remove the tape 401 from the winding core section 213.
It is to be understood that the invention is not limited to the above-described embodiment, various modifications can be made without departing from the scope of the invention. For example, in addition to the above-described embodiment, the embodiment may be modified as described below.
The “continuous medium” according to the invention is not limited to the tape-shaped continuous medium such as the tape 401, and for example, the “continuous medium” may be roll paper. The length, width, and material of the “continuous medium” are also not particularly limited.
The “notch complementing unit” according to the invention is not limited to the structure for complementing a part of the notched section 229 in the circumferential direction of the winding core section 213, such as the notch complementing section 249. For example, the “notch complementing unit” may be a structure that complements the entire notched section 229.
The “notch complementing unit” according to the invention is not limited to the structure that is attached to the winding attachment body 211, such as the notch complementing section 249. For example, “notch complementing unit” may be a component provided separately from the winding attachment body 211. Furthermore, except the “notch complementing unit” the winding attachment body 211 may be omitted.
The “notch complementing unit” according to the invention is not limited to the structure in which the “notch complementing unit” pivots between the contact position and the separated position, such as the notch complementing section 249. For example, the “notch complementing unit” may be a component that parallelly moves between the contact position and the separated position. Similarly, the “medium holding unit” according to the invention is not limited to the structure in which the “medium holding unit” pivots between the holding position and the non-holding position, such as the tape holding section 283. For example, the “medium holding unit” may be a component that parallelly moves between the holding position and the non-olding position.
To the tape printing apparatus 101 according to the embodiment, a “printing apparatus” according to the invention may be applied. Specifically, the tape printing apparatus 101 may include components similar to those in the winding core section 213 and the notch complementing section 249 according to the embodiment. In other words, the tape printing apparatus 101 and the winding apparatus 201 may be integrally provided. The “printing apparatus” according to the embodiment of the invention is not limited to the structure for performing printing onto a tape-shaped medium. For example, “printing apparatus” may perform printing onto roll paper. The “printing unit” according to the embodiment of the invention is not limited to the structure for printing by a thermal method, such as the thermal head. For example, “printing unit” may be a structure for printing by an ink jet method, an electrophotographic method, or a dot impact method.
The entire disclosure of Japanese Patent Application No. 2018-066430, filed Mar. 30, 2018 is expressly incorporated by reference herein.
Number | Date | Country | Kind |
---|---|---|---|
2018-066430 | Mar 2018 | JP | national |