1. Field of the Invention
The present invention relates to a printer device, especially a compactly made printer device, that performs printing of letters and marks on a print object sheet by using a hot release type thermal transfer ribbon tape and a line thermal head.
2. Description of the Prior Art
In recent years, as an information of packaged goods indicated on a packaging material, there are often cases where letters and marks, such as date of manufacture, tastable time period, series number of manufacture, etc. are printed differently for each object sheet to be printed (herein referred to as a print object sheet). In such cases, the printing is often done by using a hot release type thermal transfer ribbon tape and a line thermal head.
As the printing is carried out in the manufacturing process of the packaged goods, that is, for example, in the process to package the goods, the printer device used therefor is required to be made smaller in size so as to be easily fitted without obstruction in the space of machine arrangement of the packaged goods manufacturing apparatus. In addition to this, the printer device is required to be of a simplified construction, because the printer device, as a device not directly taking part in the manufacture itself of the packaged goods, is strongly desired to be made less costly.
A line thermal head printer device comprises a line thermal head, a ribbon tape unwinding drive shaft supporting a reel of a hot release type thermal transfer ribbon tape and unwinding the ribbon tape to be fed, a ribbon tape winding drive shaft winding the ribbon tape after it has been unwound and used for the printing, a stepping motor rotationally driving these drive shafts and a guide roll guiding the ribbon tape so that the ribbon tape, after unwound, is again wound up. The arrangement of these parts and components gives a large influence on the size of the printer device.
A ribbon tape unwinding reel of a ribbon tape master roll 46 is coaxially fitted to the ribbon tape unwinding drive shaft 41 so that the ribbon tape master roll 46 is supported by the ribbon tape unwinding drive shaft 41 and the ribbon tape 43 is unwound from the ribbon tape master roll 46. The ribbon tape 43 unwound from the ribbon tape master roll 46 is fed by the feed shaft 44 and the pinch roll 45 and is finally wound around a ribbon tape winding reel of the ribbon tape winding drive shaft 42. The ribbon tape winding reel is coaxially fitted to, and supported by, the ribbon tape winding drive shaft 42.
The ribbon tape 43 fed from the ribbon tape master roll 46, while running, is lapped on a print object sheet 49 to be pinched together between the line thermal head 47 and the platen roll 48 so that printing is done onto the print object sheet 49. Numerals 50, 51 designate guide rolls guiding the running of the ribbon tape 43.
In this way, in the prior art line thermal head printer device, when seen on the plan view of
Thus, in the prior art line thermal head printer device, the ribbon tape unwinding drive shaft 41, the ribbon tape winding drive shaft 42, the feed shaft 44, the pinch roll 45, etc. are arranged to be placed on a flat plane and a relatively large flat space is required therefor. Also, the drive motor is arranged on the reverse side of these parts and components and a relatively large thickness or height of the device is required for such arrangement.
In the line thermal head printer device shown in
In this example also in which the line thermal head is of the movable type, when seen on the plan view of
Thus, in the prior art line thermal head printer devices of both of the fixed head type and the movable head type, there is a problem that the size is large and a considerable space is needed for fitting the printer device to the surrounding apparatus and hence the printer device is currently desired to be made further smaller.
It is therefore an object of the present invention to provide a line thermal head printer device in which parts and components thereof are arranged differently from the prior art line thermal head printer device so that the size of the printer device can be made remarkably smaller.
In order to achieve the above-mentioned object, the present invention provides line thermal head printer devices constructed as follows:
According to the line thermal head printer device of the present invention mentioned in (1) above, the stepping motor and the line thermal head are arranged on one side portion of the frame plate and on one side of them on the frame plate, the ribbon tape unwinding drive shaft and the ribbon tape winding drive shaft are arranged so that the line connecting the stepping motor and the line thermal head inclinedly crosses with the line connecting the ribbon tape unwinding drive shaft and the ribbon tape winding drive shaft. Thereby, the parts and components constituting the line thermal head printer device are efficiently arranged without an unused space on the flat surface of the frame plate usually of a square or rectangular shape. Also, the ribbon tape fed between each of the reels supported to both of the drive shafts are led to run around these parts and components, that is, along the periphery of the frame plate. Thereby, the surface of the frame plate is effectively used and the construction of the parts and components can be made further compact.
According to the line thermal head printer device of the present invention mentioned in (2) above, in which the line thermal head is of the fixed type, the stepping motor is arranged such that the line along each side of the frame of the square or rectangular shape of the stepping motor is inclined relative to the line of each side of the one corner portion where the stepping motor is arranged. Thereby, the stepping motor is effectively arranged relative to the ribbon tape on the surface of the frame plate.
According to the line thermal head printer device of the present invention mentioned in (3) above, in which the line thermal head is of the movable type, the stepping motor and the line thermal head are arranged so that the line thermal head is given with a sufficient space for movement without obstruction. Moreover, the ribbon tape unwinding drive shaft and the ribbon tape winding drive shaft are arranged on one side of the stepping motor and the line thermal head. Thereby, the ribbon tape led between these drive shaft is given with a sufficient space by which the ribbon tape is stably supported.
According to the line thermal head printer device of the present invention mentioned in (4) above, the ribbon tape unwinding drive shaft is arranged on one side of the line thermal head and the ribbon tape winding drive shaft is arranged on one side of the stepping motor. Thereby, the space on the frame plate can be efficiently used for leading the ribbon tape.
In this way, according to the line thermal head printer device of the present invention, as compared with the conventional printer device, such a printer device as is made smaller in size approximately by three quarters, or approximately to a quarter, in the volumetric ratio can be provided.
Herebelow, the present invention will be described more concretely based on embodiments of a line thermal head printer device according to the present invention with reference to
A ribbon tape unwinding reel of a ribbon tape master roll 12 is fitted to the ribbon tape unwinding drive shaft 1 so that the ribbon tape master roll 12 is supported by the ribbon tape unwinding drive shaft 1. A ribbon tape 3 unwound from the ribbon tape master roll 12 is guided by guide rolls 4, 5, 6, 7 and 8, that are fitted to a frame plate 9, to be finally wound around a ribbon tape winding reel of the ribbon tape winding drive shaft 2. The ribbon tape winding reel is fitted to, and supported by, the ribbon tape winding drive shaft 2.
The stepping motor 10 is arranged on the left-hand side upper corner portion, as mentioned above, and functions to rotationally drive the ribbon tape unwinding drive shaft 1. The stepping motor 10 has a frame of an approximately square shape, as seen on the plan view of
Also, on the left-hand side lower corner portion adjacent to the stepping motor 10, the line thermal head 11 is arranged.
Where a line 13 is drawn connecting approximately central portions of the stepping motor 10 and the line thermal head 11, respectively, and a line 14 is drawn connecting approximately central portions of the ribbon tape unwinding drive shaft 1 and the ribbon tape winding drive shaft 2, respectively, the lines 13, 14 cross with each other so that an inclined V-shape is formed by them, as shown in
In the printer device of
Also, the parts and components are arranged so that the line 13 connecting the stepping motor 10 and the line thermal head 11 and the line 14 connecting the ribbon tape unwinding drive shaft 1 and the ribbon tape winding drive shaft 2 cross with each other to form the inclined V-shape. Thereby, within a size of an external shape as large as a post card, such a space arrangement of the parts and components as is able to use a ribbon tape master roll of a size beyond a maximum outer diameter of 60 mm is realized.
Further, with respect to winding of the ribbon tape, a distance of the roll arrangement between the guide roll 6 arranged immediately downstream of the line thermal head 11 and the next guide roll 7 is made larger relative to a width of the ribbon tape that is being used. Thereby, such an effect can be obtained that no influence of a winding looseness that is generated from the ribbon tape on the winding side reaches the line thermal head 11.
A ribbon tape unwinding reel of a ribbon tape master roll 30 is fitted to the ribbon tape unwinding drive shaft 21 so that the ribbon tape master roll 30 is supported by the ribbon tape unwinding drive shaft 21. A ribbon tape 23 unwound from the ribbon tape master roll 30 is guided by guide rolls 24, 25, 26, 27 and 28, that are fitted to a frame plate 29, to be finally wound around a ribbon tape winding reel of the ribbon tape winding drive shaft 22. The ribbon tape winding reel is fitted to, and supported by, the ribbon tape winding drive shaft 22.
The stepping motor 31 is arranged on the left-hand side upper corner portion, as described above, and functions to rotationally drive the ribbon tape unwinding drive shaft 21. The stepping motor 31 has a frame of an approximately square shape, as seen on the plan view of
Also, on the left-hand side lower corner portion adjacent to the stepping motor 31, the line thermal head 32 is arranged. Numeral 34 designates a slider guide of the line thermal head 32. The slider guide 34 has a slide groove 35 along which a slider 33 supporting the line thermal head 32 slides. While the slider 33 is so sliding, printing is carried out on the print object sheet (not shown).
Where a line 36 is drawn connecting approximately central portions of the stepping motor 31 and the line thermal head 32 when it is on the left-hand side end position of the slide groove 35, respectively, and a line 37 is drawn connecting approximately central portions of the ribbon tape unwinding drive shaft 21 and the ribbon tape winding drive shaft 22, respectively, the lines 36, 37 cross with each other so that an inclined inverse V-shape is formed by them, as shown in
In the printer device shown in
Also, the parts and components are arranged so that the line 36 connecting the stepping motor 31 and the line thermal head 32 and the line 37 connecting the ribbon tape unwinding drive shaft 21 and the ribbon tape winding drive shaft 22 cross with each other to form the inclined inverse V-shape. Thereby, within a size of an external shape as large as a post card, such a space arrangement of the parts and components as is able to use a ribbon tape master roll of a size beyond a maximum outer diameter of 60 mm is realized.
Further, with respect to winding of the ribbon tape, a distance of the roll arrangement between the guide-roll 26 arranged immediately downstream of the line thermal head 32 and the next guide roll 27 is made larger relative to a width of the ribbon tape that is being used. Thereby, such an effect can be obtained that no influence of a winding looseness that is generated from the ribbon tape on the winding side reaches the line thermal head 32.
In the above, while the present invention has been described concretely based on the embodiments as illustrated, the present invention is not limited thereto but, needless to mention, may be added with variations or modifications within the scope of the claims as appended hereto.
For example, in the embodiments as illustrated, while the arrangement is made such that the ribbon tape winding drive shaft is arranged on one side of the stepping motor and the ribbon tape unwinding drive shaft is arranged on one side of the line thermal head, the arrangement may be made with the two drive shafts being reversely arranged to each other, that is, the ribbon tape unwinding drive shaft is arranged on one side of the stepping motor and the ribbon tape winding drive shaft is arranged on one side of the line thermal head.
Also, in the embodiments shown in
Number | Date | Country | Kind |
---|---|---|---|
2003-410085 | Dec 2003 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5052832 | Akiyama et al. | Oct 1991 | A |
5260716 | Maslanka | Nov 1993 | A |
5853254 | Inakoshi et al. | Dec 1998 | A |
6232993 | Kobayashi et al. | May 2001 | B1 |
20020094222 | Furuya et al. | Jul 2002 | A1 |
20040208682 | Akaiwa et al. | Oct 2004 | A1 |
Number | Date | Country |
---|---|---|
1 253 018 | Oct 2002 | EP |
7-290805 | Nov 1995 | JP |
Number | Date | Country | |
---|---|---|---|
20050122387 A1 | Jun 2005 | US |