JP2011073346A - Cassette for thermal transfer sheet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cassette for a thermal transfer sheet which can be discarded after use, and can suppress the deformation of a rod. <P>SOLUTION: The cassette 10 for the thermal transfer sheet is equipped with a core holding body 11 having a holding section 13 of a winding core and a holding section 12 of a feeding core and lid bodies 21, 20 covering the holding section 13 of the winding core and the holding section 12 of the feeding core, respectively. A rod 30 for guiding the thermal transfer sheet 5 is arranged in the core holding body 11 and the both ends of the rod 30 are held by a pair of bearings 31, 31. Furthermore, the rod 30 is arranged at the winding core 3 side and pushed to the outside of the core holding body 11 by the thermal transfer sheet 5. The rod 30 is formed of a solid resin shaft, and the resin shaft has a Young's modulus of 2.43×10<SP>3</SP>to 6.95×10<SP>3</SP>(E/mm<SP>2</SP>). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a thermal transfer sheet cassette that houses a sheet body made of a thermal transfer sheet.

  Conventionally, a sheet body having a winding core, a supply core, and a thermal transfer sheet is known. The sheet body is stored in a thermal transfer sheet cassette including a winding core holding portion, a core holding body having a supply core holding portion, and a lid body covering the core holding body (for example, Patent Document 1). reference).

  In the cassette, the thermal transfer sheet is fed out from the supply core and wound around the winding core. During this time, the thermal transfer sheet is heated by the thermal head, and the image is transferred from the thermal transfer sheet to the image receiving sheet.

  By the way, when the thermal transfer sheet is fed out in the cassette, the thermal transfer sheet may come into contact with the inner surface of the cassette, which may hinder the winding of the thermal transfer sheet by the winding core. For this reason, a rod for guiding the thermal transfer sheet may be provided in the cassette (see, for example, Patent Document 2).

US Pat. No. 5,110,228 JP 2006-212819 A

  As such a rod, a metal rod is generally used in general. However, since the metal rod has a relatively high material cost and processing cost, the manufacturing cost of the entire cassette also increases. When the thermal transfer sheet cassette is discarded after use, it is necessary to remove only the metal rod from other members and discard it. On the other hand, it is also conceivable to use a relatively inexpensive rod made of synthetic resin. However, in this case, since the rod made of synthetic resin is more easily deformed than the rod made of metal, when the thermal transfer sheet is wound up, a force may be applied to the rod and the rod may be bent.

  The present invention has been made in consideration of such points, and an object thereof is to provide a thermal transfer sheet cassette that can be easily discarded after use and in which the rod does not deform during use. .

The present invention relates to a thermal transfer sheet cassette for storing a winding core, a supply core, and a thermal transfer sheet that is wound around the winding core and the supply core and heated by a thermal head. A core holding body having a portion, a supply core holding portion, a pair of connecting portions connecting the holding core holding portion and the supply core holding portion, and a winding side cover that covers the holding portion of the winding core And a supply-side lid that covers the holding portion of the supply core, and a synthetic resin rod that is provided between the pair of connecting portions of the core holding body and that contacts the thermal transfer sheet and guides the thermal transfer sheet. The both ends of the rod are rotatably held by a pair of bearings provided on the core holder, and the rod is disposed on the winding core side and pressed outward of the core holder by the thermal transfer sheet. The resin shuff Made, the resin shaft has a solid shape, a thermal transfer sheet cassette characterized by having a Young's modulus of ^{2.43 × 10 3 ~6.95 × 10 3} (E / mm 2).

  The present invention is the thermal transfer sheet cassette, wherein the resin shafts have the same outer diameter along the axial direction.

  The present invention relates to a thermal transfer sheet cassette characterized in that the resin shaft has a small-diameter central portion and large-diameter end portions, and the outer diameter gradually increases from the central portion toward both end portions. is there.

  The present invention is the thermal transfer sheet cassette, wherein the resin shaft is made of glass fiber-containing PBT.

  The present invention is a thermal transfer sheet cassette characterized in that a plurality of receiving projections are provided along the axial direction of the rod on the winding side lid so as to receive a suppression force from the thermal transfer sheet applied to the rod in contact with the rod. is there.

  As described above, according to the present invention, the thermal transfer sheet is smoothly guided by the rod in the cassette, so that the thermal transfer sheet does not come into contact with the inner surface of the cassette, and the thermal transfer sheet can be smoothly fed out or wound up. .

  Further, according to the present invention, the rod is made of a resin shaft, and the resin shaft has a solid shape and has a Young's modulus of A to B. Therefore, even when a force is applied to the rod when the thermal transfer sheet is wound. There is no risk of rod deformation. Furthermore, since the rod is made of a resin shaft, when the thermal transfer sheet cassette is discarded after use, only the rod need not be removed by other members and can be discarded as a whole.

The perspective view which shows one Embodiment of the cassette for thermal transfer sheets by this invention. The top view which shows one Embodiment of the cassette for thermal transfer sheets by this invention. The side view in the assembly state of the cassette for thermal transfer sheets. The top view which shows a winding side cover body. AA line sectional view of Drawing 4. Schematic which shows the effect | action of a receiving protrusion. The figure which shows the relationship between a thermal transfer sheet, a rod, and a thermal head. The side view which shows a rod.

  Embodiments of the present invention will be described below with reference to the drawings.

1 to 7 are views showing an embodiment of a thermal transfer sheet cassette according to the present invention.
Here, FIG. 1 is a perspective view showing an embodiment of the present invention, and FIG. 2 is a plan view showing the embodiment of the present invention. FIG. 3 is a side view of the thermal transfer sheet cassette in an assembled state, and FIG. 4 is a plan view showing the winding side lid. FIG. 5 is a cross-sectional view taken along line AA in FIG. 4, and FIG. FIG. 7 is a diagram showing the relationship among the thermal transfer sheet, the rod, and the thermal head. FIG. 8 is a side view showing the rod.

  As shown in FIGS. 1 to 7, the thermal transfer sheet cassette 10 is a sheet body 1 including a winding core 3, a supply core 2, and a thermal transfer sheet 5 wound around the winding core 3 and the supply core 2. Is to be stored.

  The thermal transfer sheet 5 in the thermal transfer sheet cassette 10 is unwound from the supply core 2 and taken up by the take-up core 3. During this time, the thermal transfer sheet 5 is heated by the thermal head 5b and the image is transferred to the image receiving sheet 5a ( FIG. 7).

  The winding core 3 and the supply core 2 both have flanges 3b and 2b. The winding core 3 and the supply core 2 both have positioning ratchets 3a and 2a.

  The thermal transfer sheet cassette 10 that stores the sheet body 1 having such a configuration includes a winding core holding portion 13 that holds the winding core 3, a supply core holding portion 12 that holds the supply core 2, and these A core holding body 11 having a pair of connecting parts 17 for connecting the holding part 13 of the take-up core and the holding part 12 of the supply core, and the holding part 13 of the winding core of the core holding body 11 and the holding of the supply core And a pair of lid bodies (winding side lid body 21 and supply side lid body 20) that cover the portion 12.

  Among these, the winding side cover 21 covers the holding part 13 of the winding core, and the supply side cover 20 covers the holding part 12 of the supply core.

  As shown in FIG. 2, the take-up core holding portion 13 of the core holding body 11 has an open bearing 13 a that holds the shaft 3 c of the take-up core 3 and opens upward, and holds the supply core holding portion 12. Has an opening bearing 12a that holds the shaft 2c of the supply core 2 and opens upward.

  Each of the open bearings 13a and 12a opens upward, and is adapted to fit and support the shaft 3c of the winding core 3 and the shaft 2c of the supply core 2 fitted from above.

  Further, a rod 30 is provided between the pair of connecting portions 17 of the core holder 11 so as to contact the thermal transfer sheet 5 and rotatably support and guide the thermal transfer sheet 5. The rod 30 is disposed on the side opposite to the thermal head 5b with respect to the thermal transfer sheet 5, and the rod 30 is disposed on the side opposite to the core holder 11 with respect to the thermal transfer sheet 5 (FIG. 7).

The rod 30 is made of a resin shaft having shafts 30a at both ends, and this resin shaft has a solid shape. The rod 30 has the same outer diameter (for example, 3φ) along the axial direction as shown in FIG. 8 (a). However, as shown in FIG. 8 (b), the rod 30 and the thick central portion 30b (for example, 2φ) You may have the diameter both ends 30c (for example, 3phi). In FIG. 8B, the outer diameter of the rod 30 gradually increases from the central portion 30b toward both end portions 30c.
As shown in FIG. 8B, when the rod 30 whose outer diameter gradually increases from the central portion 30b toward both end portions 30c is used, the thermal transfer sheet 5 is pulled to both end sides, so that the thermal transfer sheet is wrinkled. There is nothing.
The resin shaft of the rod 30 is made of a synthetic resin, but is made of a material having a relatively high hardness.
Examples of the material of the resin shaft of the rod 30 include acrylic resin, 30 wt% glass fiber (GF) -containing PBT (polybutylene terephthalate) resin, PC (polycardnate) resin, PS (polystyrene) resin, and the like.
The above-mentioned materials constituting the rod 30 are all hard and have a Young's modulus of 2.43 × 10 ^{3 to} 6.95 × 10 ³ N / mm ² .
In particular, when the rod 30 is formed from a glass fiber-containing PBT resin, the glass fiber-containing PBT resin has a Young's modulus of 6.95 × 10 ³ N / mm ² , so that when the thermal transfer sheet 5 is wound, the rod 30 Even if a force is applied from the thermal transfer sheet 5, the rod 30 is not deformed, and thus the thermal transfer sheet 5 is not wrinkled.
Also, since the rod 30 is made of synthetic resin, when the thermal transfer sheet cassette is discarded after use, it is not necessary to remove only the rod 30 from other members and discard it, compared to the case where the rod 30 is made of metal. .

  By the way, as shown in FIG. 1, the rod 30 is rotatably held by a pair of bearings 31, 31 provided at both ends of each connecting portion 17 of the core holder 11. Each bearing 31 protrudes from the connecting portion 17 toward the winding core 3. The rod 30 is disposed on the winding core 3 side, and is pressed outward (upward in FIG. 1) by the thermal transfer sheet 5 when the thermal transfer sheet 5 is driven.

  Further, as shown in FIGS. 1 and 4, receiving projections 26, 26 that receive a pressing force from the thermal transfer sheet 5 that contacts the rod 30 and is applied to the rod 30 are provided on the winding-side lid 21 in the axial direction of the rod 30. A plurality of (two in this embodiment) are provided. That is, the winding side lid 21 has a flat portion 21 a extending along the width direction of the winding side lid 21, and the receiving protrusions 26 and 26 are the outermost edges of the flat portion 21 a of the winding side lid 21. Is provided. As shown in FIG. 5, the receiving projection 26 has an arc surface 26 a that abuts on the rod 30 when the thermal transfer sheet 5 is driven.

  As described above, the rod 30 is brought on the side opposite to the thermal head 5b with respect to the thermal transfer sheet 5 and on the side opposite to the core holder 11 with respect to the thermal transfer sheet 5, so that the thermal head 5b When pressed, the rod 30 is directed outward from the core holder 11. In particular, it is conceivable that the rod 30 is lifted and bent at the center of the rod 30 away from the bearings 31 and 31. On the other hand, in the present embodiment, since the receiving projections 26 and 26 that receive the pressing force from the thermal transfer sheet 5 are provided on the winding side lid 21, the rod 30 is prevented from being lifted and deformed. (FIG. 6).

  Further, since the rod 30 is held in the bearing 31, the rod 30 can be easily accommodated in the bearing 31 only by inserting the rod 30 into the bearing 31 from the lateral direction.

  As shown in FIGS. 1 and 2, a receiving portion 15 with which the take-up core 3 abuts is provided on one side (left side) of the take-up core holding portion 13, and one side of the supply core holding portion 12 is provided. A receiving portion 14 with which the supply core 2 abuts is also provided on the (left side). Further, as shown in FIG. 2, the winding core 3 and the supply core 2 are placed on the outer sides of the shaft 3c of the winding core 3 and the shaft 2c of the supply core 2 toward the other side (right side) of the holding portions 13 and 12, respectively. The springs 6 and 6 are pressed.

  When the thermal transfer sheet 5 is driven, a driving mechanism (not shown) is inserted from the other side (right side) of the winding core holding portion 13 and the supply core holding portion 12, and this driving mechanism resists the force of the springs 6 and 6. Then, the winding core 3 and the supply core 2 are moved to the left side in FIG. 2, and the winding core 3 and the supply core 2 are driven to rotate.

  When the thermal transfer sheet 5 is stopped, the drive mechanism is separated from the take-up core 3 and the supply core 2, and the take-up core 3 and the supply core 2 are moved to the right in FIG. Engage the winding core 3 and the supply core 2 by engaging the ratchet 3a, 2a of the supply core 2 with the engaging portion 19 of the corresponding winding core holding portion 13 and the engaging portion 18 of the holding core holding portion 12. It comes to stop (FIG. 2). The engaging portions 19 and 18 are formed of protrusions that protrude from the bottom surfaces of the holding portions 13 and 12, respectively.

  Furthermore, a plurality of rectangular through holes 22 and 23 are provided on the inner surfaces of the holding part 12 and the holding part 13 of the core holder 11 (four in this embodiment, respectively). Are provided with a plurality of protrusions 24 and 25 (four in this embodiment) that are fitted into the through holes 22 and 23, respectively. That is, when covering the core holding body 11 with the lid bodies 20 and 21, the protrusions 24 and 25 of the lid bodies 20 and 21 are fitted into the corresponding holding portions 12 and the through holes 22 and 23 of the holding portion 13, respectively. Accordingly, the lid bodies 20 and 21 can be firmly fixed to the holding portion 12 and the holding portion 13 of the core holding body 11.

  Next, the operation of the present embodiment having such a configuration will be described.

  First, the sheet body 1 including the winding core 3, the supply core 2, and the thermal transfer sheet 5 is attached to the core holder 11. In this case, the winding core 3 and the supply core 2 are respectively inserted into the winding core holding part 13 and the supply core holding part 12.

  As described above, since the opening bearing 13a of the winding core holding portion 13 and the opening bearing 12a of the supply core holding portion 12 are both open upward, the shaft 3c of the winding core 3 and the supply core The shaft 3c of the winding core 3 and the shaft 2c of the supply core 2 can be easily inserted into the opening bearings 13a and 12a simply by fitting the second shaft 2c into the opening bearings 13a and 12a from above.

  Next, the rod 30 is mounted in the bearing 31 of the core holder 11 from above the thermal transfer sheet 5.

  Next, the winding-side lid 21 is put on the winding core holding portion 13 of the core holding body 11, and the supply-side lid 20 is put on the holding portion 12 of the supply core. In this case, the protrusions 24 and 25 of the lid bodies 20 and 21 are fitted into the holding portions 12 of the core holding body 11 and the through holes 22 and 23 of the holding portion 13, respectively. Accordingly, the lid bodies 21 and 20 can be firmly fixed to the winding core holding portion 13 and the supply core holding portion 12 of the core holding body 11.

  At this time, the receiving projections 26 and 26 provided on the winding side lid 21 are arranged in the vicinity of the rod 30 along the axial direction of the rod 30.

  In this way, the sheet body 1 having the thermal transfer sheet 5 can be stored and held in the thermal transfer sheet cassette 10.

  After the sheet body 1 is housed in the thermal transfer sheet cassette 10, the thermal transfer sheet cassette 10 is mounted on the printer, and the thermal transfer sheet 5 is heated by the thermal head 5b of the printer, and the image is transferred to the image receiving sheet 5a (FIG. 7).

  In this case, the thermal transfer sheet 5 is guided in the thermal transfer sheet cassette 10 by the rod 30. During this time, even if the thermal transfer sheet 5 is pressed by the thermal head 5b, the receiving projections 26 and 26 are provided on the winding-side lid 21, so that the rod 30 is not lifted and deformed. For this reason, the thermal transfer sheet 5 can be smoothly drawn out from the supply core 2 and taken up on the take-up core 3.

  Further, the rod 30 is made of a resin shaft, and the resin shaft has a solid shape and has a Young's modulus of A to B. Therefore, in addition to the receiving protrusion 26, the deformation of the rod 30 can be further suppressed. As a result, wrinkles are not generated in the thermal transfer sheet 5. Further, since the rod 30 is made of a resin shaft, when the thermal transfer sheet cassette is discarded after use, it is not necessary to remove only the rod from other members, and it can be discarded as a whole.

表−１において、しわの発生状態のうち、◎は１００枚印画しても印画物、熱転写シート５にしわが全く発生しない状態を示し、○は１００枚印画しても印画物、熱転写シート５のしわの発生率が１０％以下の状態を示し、×は１００枚印画しても印画紙、熱転写シート５のしわの発生率が１０％より多い状態を示す。
またヤング率は両持ちばりの試験機を用い、以下の（１）（２）式により求めた。
Ｅ＝ＷＬ^３／４８ｙＩ・・・（１）
Ｉ＝（π／６４）×ｄ^４・・・（２）
Ｅ：ヤング率
Ｗ：ロッドが３ｍｍたわむときの荷重（ｇ）
Ｌ：ロッドの長さ
ｙ：変位量（３ｍｍ）
Ｉ：慣性二次モーメント
ｄ：ロッドの直径（ｍｍ） Next, examples of the present invention will be described.
In this example, the following materials were used as the material of the rod 30, and the shape of the rod 30 shown in FIG. 8A and the shape shown in FIG. 8B was used.
Wrinkles generated in the thermal transfer sheet 5 at this time are detected, and the results are shown in Table 1 below.

In Table 1, among the wrinkle generation states, ◎ indicates a state in which no wrinkles are generated on the printed matter and the thermal transfer sheet 5 even when 100 sheets are printed, and ○ indicates that the printed matter and the thermal transfer sheet 5 are not printed even if 100 sheets are printed. The wrinkle generation rate indicates a state of 10% or less, and x indicates a state where the wrinkle generation rate of the photographic paper and the thermal transfer sheet 5 is higher than 10% even after printing 100 sheets.
The Young's modulus was obtained by the following formulas (1) and (2) using a dual holding tester.
E = WL ³ / 48yI (1)
I = (π / 64) × d ⁴ (2)
E: Young's modulus W: Load when the rod bends 3 mm (g)
L: Rod length y: Displacement amount (3 mm)
I: moment of inertia d: rod diameter (mm)

DESCRIPTION OF SYMBOLS 1 Sheet body 2 Supply core 3 Winding core 5 Thermal transfer sheet 6 Spring 10 Thermal transfer sheet cassette 11 Core holding body 12 Supply core holding portion 12a Opening bearing 13 Winding core holding portion 13a Opening bearings 14 and 15 Receiving portion 17 Connection Parts 18 and 19 Engagement part 20 Supply side lid 21 Winding side lid 21a Flat part 22, 23 Through hole 24, 25 Protrusion 26 Receiving protrusion 30 Rod 31 Bearing

Claims (5)

In the thermal transfer sheet cassette for storing a sheet body composed of a winding core, a supply core, and a thermal transfer sheet wound around the winding core and the supply core and heated by a thermal head,
A core holding body having a holding part for the winding core, a holding part for the supply core, and a pair of connecting parts for connecting the holding part for the winding core and the holding part for the supply core;
A winding side cover that covers the holding portion of the winding core;
A supply-side lid that covers the holding portion of the supply core;
Provided between a pair of connecting portions of the core holder, and a synthetic resin rod that contacts the thermal transfer sheet and guides the thermal transfer sheet;
Both ends of the rod are rotatably held by a pair of bearings provided on the core holder,
The rod is arranged on the winding core side and pressed outward of the core holder by the thermal transfer sheet,
The rod is made of a resin shaft, and the resin shaft has a solid shape and has a Young's modulus of 2.43 × 10 ^{3 to} 6.95 × 10 ³ (E / mm ² ). Cassette.   2. The thermal transfer sheet cassette according to claim 1, wherein the resin shafts have the same outer diameter along the axial direction.   2. The thermal transfer sheet cassette according to claim 1, wherein the resin shaft has a small-diameter central portion and large-diameter end portions, and the outer diameter gradually increases from the central portion toward both end portions. .   2. The thermal transfer sheet cassette according to claim 1, wherein the resin shaft is made of glass fiber-containing PBT.   2. The thermal transfer sheet cassette according to claim 1, wherein a plurality of receiving projections are provided on the winding side cover body so as to receive pressure from the thermal transfer sheet applied to the rod in contact with the rod along the axial direction of the rod. .

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