BACKGROUND OF THE INVENTION
Field of the Invention
[0001] The present invention relates to a thermal transfer printer in which the major scanning
is carried out by a thermal head and the minor scanning is carried out by the intermittent
turning of the platen via a timin
q belt bv means of a step motor.
Description of the Prior Art
[0002] As a thermal transfer printer there has generally been known a type in which one
line is printed by pressing a thermal head, via an ink ribbon, against the recording
paper which is wound on the platen, and the printing of the next line is carried out
by intermittently turning the platen. An example of the prior art thermal transfer
printer of the above kind will be described by referring to Figs. 1 to 3.
[0003] As shown in Figs. 1 and 2, the thermal transfer printer includes a step motor 10
which is arranged to turn a platen 14 intermittently through a timing pulley 12 and
a timing belt 18 that is wound round a timing pulley mounted on the platen 14. Here,
the upper running portion of the timing belt 18 is set to be the tension side of the
belt.
[0004] On the other hand, an ink ribbon 20 is arranged to be forwarded a ribbon feeding
motor 21 and by a conveyor roller for ribbon winding 22 to an ink ribbon reel 24 by
passing directly underneath the platen 14. With the ink ribbon in between, a line-form
thermal head 26 is arranged facing the platen 14.
[0005] Moreover, the recording paper 28 is fed from the paper supply cassette by a paper
supply roller 32, runs between the platen 14 and the ink ribbon 20 through guide plates
33 and a guide roller 35, and is printed on by the thermal head 26 after running round
the platen 14 for about one half of its circumference. The recording paper 28 which
has been printed is sent out to the paper removal tray 36 by a forwarding roller 34.
The thermal transfer printer further includes a power supply unit 37 for driving the
step motor and a controller 38 for controlling the turning operation and the like
of the platen 14. The shaft 40 of the platen 14 is supported by the bearinqs 44 prepared
on the frame 42 (see fig. 3).
[0006] In the prior art thermal transfer printer with the above construction, the major
scanning is carried out by the thermal head 26 while the minor scanning is carried
out by the intermittent turning of the platen 14. Namely, the ink ribbon 20 is brought
to a direct contact with the recording paper 28 which is wound round the platen 14,
and the printing is accomplished by thermal transcription with the thermal head 26.
In this operation, the thermal head 26 is pressed against the platen 14 with a force
of several kg-weight so that there is required a large torque in order to turn the
platen 14 intermittently. On the timing belt there is applied an intermittent tension
due to the intermittent drive of the platen 14. Owing to the intermittent tension
and the friction load on the thermal head 26, there is applied a force in the radial
direction of the shaft of the platen 40 which varies periodically. The force is transmitted
to the frame 42 to generate a noise by causing the frame to vibrate.
[0007] In order to prevent the transmission of vibrations like in the above and to suppress
the generation of a noise, there has been tried in the past to insert cylindrical
anti-vibration rubber pieces between the frame 42 and the bearings 44 that support
the shaft 40 of the platen. However, such an attempt gives rise to a possibility of
reducing the printing accuracy due to the relative shift in the positions between
the thermal head 26 and the platen 14.
SUMMARY OF THE INVENTION
[0008] An object of the present invention is to provide a thermal transfer printer which
produces a low noise and yet possesses a high printing accuracy.
[0009] Another object of the present invention is to provide a thermal transfer printer
which is adapted for suppressing the generation of a noise caused by the intermittent
turning of the platen.
[0010] One feature due to the present invention is that, in a thermal transfer printer for
thermally recording an information on the recording paper, there are installed a platen
for winding the recoridng paper, a thermal head for thermally recording an information
on the recording paper, a step motor for intermittently turning the platen via a timing
belt, and a timing pulley mounted on the platen that has a timing belt wound round
it for transmitting the driving power from the step motor to the platen, and the timing
pulley is given a construction in which it is composed of an inner ring, an outer
ring and a buffer cylinder which is inserted between the inner and the outer rings.;
[0011] These and other objects, features and advantages of the present invention will be
more apparent from the following description of the preferred embodiments taken in
conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012]
Figure 1 is an overall side view of a prior art thermal transfer printer;
Fig. 2 is the side view of the platen and step motor section of the printer shown
in Fig. 1;
Fig. 3 is the plan view of the section shown in Fig. 2;
Fig. 4 is a schematic side view of the platen section of a thermal transfer printer
embodying the present invention;
Fig. 5 is the plan view of the platen section shown in Fig. 4;
Fig. 6 is a block diagram for the vibration system corresponding to the embodiment
shown in Fig. 4;
Figs. 7A and 7B are the block diagrams for the vibration systems corresponding to
the prior art thermal transfer printers;
Fig. 8 is a power level chart of noises for the embodiment shown in Fig. 4 and the prior art device shown in Fig. 7A;
Fig. 9 is a schematic side view of a second embodiment in accordance with the present
invention;
Fig. 10 is a graph illustrating a characteristic of the embodiment shown in Fig. 9;
Fig. 11 is a schematic side view of a third embodiment in accordance with the present
invention;
Fig. 12 is a schematic side view of a fourth embodiment in accordance with the present
invention; and Fig. 13 is a schematic side view of a fifth embodiment in accordance
with the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0013] Referring to Figs. 4 and 5, there is shown the platen section of a thermal transfer
printer embodying the present invention.
[0014] In the thermal transfer printer, identical symbols are given to the elements that
are identical to those in the prior art thermal transfer printer shown in Figs. 1
to 3 to omit further explanation.
[0015] The thermal transfer printer includes a timing pulley 50 constructed by a plain cylindrical
inner ring'SOa which is fitted and fixed directly to the shaft 40 of the platen, and
an outer ring 50c, with teeth on its outer peripheral surface, which is fitted to
the inner ring 50a via an elastic buffer cylinder 50b.
[0016] In the thermal transfer printer of the present invention with the above construction,
the force that is exerted on the platen in its radial direction by the timing belt
18 at the time of intermittent turning of the timing pulley 50, is mollified by the
buffer cylinder 50b. In Fig. 6, there is illustrated a vibration model for the radial
direction of the shaft of the platen in the thermal transfer printer of the present
invention shown in Fig. 4, in Fig. 7A is illustrated a vibration model for the radial
direction of the shaft of the platen for the prior art thermal transfer printer in
which no use is made of a buffer, and in Fig. 7B is illustrated a vibration model
for the radial direction of the shaft of the platen for the prior art thermal transfer
printer in which a buffer is inserted between the bearings and the frame. In these
figures, Ma represents the mass of the outer ring 50c of the timing pulley on the
platen side, m is the sum of the masses of the platen 14 and the inner ring 50a of
the timing pulley 50, Mal is the mass of the timing pulley 50, m
al is the mass of the platen 14, K and Kl represent the spring constant, and F represents
the external force that acts on the timing pulley 50 due to the intermittent tension
on the timing belt 18.
[0017] In the prior art device shown in Fig. 7A, the external force F is transmitted to
the frame 42 as is beacuse of the rigid joining of the varions elements such as the
timing pulley 50 and the shaft 40 of the platen. In the case of the prior art device
in which a buffer cylinder is inserted between the frame 42 and the bearings 44, as
shown by Fig. 7B, the timing pulley 50 and the platen (with mass Mal + mal) constitute
a system of forced vibration with one degree of freedom. That the transmissibility
of the external force F to the frame 42 in this case will be less than unity for the
range of frequency which is above the square root of two times the resonance frequency
is well known. However, since the platen 14 in the vibration model is situated nearer
the external force F than the elastic body, the displacement is larger than in the
case of rigid joining to the frame as shown in Fig. 7A. Therefore, there is
[0018] generated a relative displacement of the platen with respect to the thermal head
26, readucing the printing accuracy. In the vibration model shown in Fig. 6 for the
thermal transfer printer in accordance with the present invention, what appears on
the side of the external force F is the outer ring 50c with mass Ma, of the timing
pulley, and there is formed a system of forced vibration with one degree of freedom.
The transmissibility of the external force F becomes less than unity for the range
of frequency which is above square root of two times the resonance frequency
[0019] so that it becomes possible to reduce the generation of noise due to the external
force F in the radial direction of the shaft of the platen 40. It is to be noted that
what is displaced due to the intermittent tension on the timing belt 18 is the outer
ring 50c alone of the timing pulley 50. Since there will be created no relative displacement
between the platen 14 and the thermal head 26, no reduction in the printing accuracy
will be generated.
[0020] In Fig. 8 are compared the results of measurement on the acoustic power level for
the prior art thermal transfer printer shown in Fig. 7A and for the thermal transfer
printer in accordance with the present invention. From the figure, it will be seen
that a reduction of 5 dB in the acoustic power level of the noise can be achieved
by the use of the device of the present invention.
[0021] Referring to Fig. 9, there is illustrated a second embodiment of the thermal transfer
printer in accordance with the present invention. This embodiment shows an example
in which the present invention is applied to the case where a high accuracy in the
direction of paper feeding is required for carrying out superposed impressions as
for the color printing. In the embodiment, there are created on the buffer cylinder
50b a plurality of equally spaced radial notches 54 that extend from its outer periphery
toward the center, and on the inner periphery of the outer ring 50c there are fixed
wings 56, consisting of projections that fit the notches 54, that are made of a material,
such as metal or plastic, with elastic modulus greater than that for the elastic body
constituting the buffer cylinder 50b.
[0022] Generally, the torsional spring constant k of a cylindrical anti-vibration rubber
piece is given by the following expression.
[0023] In the above expression, G is the shearing modulus, I is the axial length of the
cylinder, and r
1 and r
2 represent the inner and outer radius, respectively.
[0024] Equation (1) may be rewritten as
[0025] where
r2/rl = α >1 ) . Shown in fig. 10 is α
2/(α
2-1) as a function of α . It will be seen from the figure that the spring constant
K increases as approaches unity.
[0026] Now, it should be noted that the provision of wings 56 as in the embodiment shown
in fig. 9 results in a reduction in the effective length in which there is generated
a shearing stress in the direction of rotation of the buffer cylinder 50b, which becomes
approximately equivalent to letting« approach unity.
[0027] On the other hand, the spring constant in the radial direction of the buffer cylinder
50b can be represented as the sum of spring cosntant due to shearing stress and the
spring constant due to compression and tension. Generally speaking, the spring constant
due to shearing is small compared with that due to compression and tension so that
the spring constant in the radial direction of the cylindrical anti-vibration rubber
piece is dominated by the spring constant due to compression and tension. Therefore,
even when the torsional spring constant of the buffer cylinder 50b is increased by
the wings 56, the increase in the spring constant in the radial direction will not
be appreciable. As a result, it becomes possible to suppress the transmissibility
vibrations to the platen 14 and the shaft of the platen 40, as well as to secure the
accuracy in the direction of paper feeding.
[0028] Referring to Fig. 11, there is shown a third embodiment of the thermal transfer printer
in accordance with the present invention. In this embodiment, there are provided notches
54a, which are similar to the previous notches 54, on the inner periphery of the buffer
cylinder 50b, and on the inner ring 50a of the timing pulley 50 there are provided
wings 56a which are similar to the previous wings 56. For this embodiment, the same
effects as in the embodiment shown in Fig. 9 can be obtained.
[0029] Referring to Fig. 12, there is shown a fourth embodiment of the thermal transfer
printer in accordance with the present invention. In this embodiment, wings 56a on
the inner ring 50a of the timing pulley and wings 58 on the outer ring 50c of the
timing pulley are installed with their respective positions alternating. For this
embodiment, too, there are obtained effects similar to those in the previous embodiments.
[0030] Referring to Fig. 13, there is shown a fifth embodiment of the thermal transfer printer
in accordance with the present invention.
[0031] In this embodiment, there are previded cylindrical projections 60 along the inner
periphery of the outer ring 50c of the timing pulley. These projections 60 are made
of a material- with elastic modulus which is greater than that of the elastic body
that constitutes the buffer cylinder 50b. Fcr this embodiment, too, effects similar
to those of the embodiments described in the foregoing can be obtained.
[0032] In summary, a thermal transfer printer in accordance with the present invention can
suppress the generation of the noise created by the intermittent turning of the platen,
without reducing the printing accuracy to any degree. Therefore, it can prevent the
increase in noise within an office accompanying the spread of office automation.
[0033] Various modifications will become possible for those skilled in the art after receiving
the teachings of the present disclosure without departing from the scope thereof.
l. A thermal transfer printer for thermally recording information on a recording paper,
characterized by:
a platen (14) for winding the recording paper;
a thermal head (26) for thermally recording information on the recording paper;
a timing pulley (50) installed at said platen (14) for transmitting to said platen
the driving power which is supplied through a timing belt (18), in order to turn said
platen (14) intermittently; and
buffer means (50b) arranged on the external force side of said platen (14) for absorbing
the external force that acts on said timing pulley (50) due to the intermittent tension
of the timing belt (18).
2. A thermal transfer printer as claimed in Claim 1, in which said thermal head (26)
is mounted fixedly to the frame that supports said platen (14).
3. A thermal transfer printer as claimed in Claim 1 or 2, in which said buffer means
(50b) is disposed in said timing pulley (50).
4. A thermal transfer printer as claimed in Claim 3, in which said timing pulley comprises
an outer ring (50c) and an inner ring (50a), and said buffer means comprises a buffer
cylinder (50b) inserted between the outer ring and the inner ring.
5. A thermal transfer printer as claimed in Claim 4, in which the buffer cylinder
comprises an elastic body.
6. A thermal transfer printer as claimed in Claim 5, in which the buffer means further
comprises a plurality of projecting parts installed protrusively in the radial direction
of said tiding pulley from the inner periphery of the outer ring (50c) of said timing
pulley, so as to fit notches provided in the buffer cylinder (50b), and the projecting
parts are made of a material with elastic modulus which is greater than that of the
elastic body that constitutes the buffer cylinder.
7. A thermal transfer printer as claimed in Claim 5, in which said buffer means further
comprises a plurality of projecting parts installed protrusively in the radial direction
of said timing pulley from the outer periphery of the inner ring (50a) of said timing
pulley, so as to fit notches provided in the buffer cylinder (50b), and the projecting
parts are made of a material with elastic modulus which is greater than that of the
elastic body that constitutes the buffer cylinder.
..8. A thermal transfer printer as claimed in Claim 5, in which said buffer means
further comprises a plurality of projecting parts that are installed alternately on
the inner periphery of the outer ring (50c) and on the outer periphery of the inner
ring (50a), of said timing pulley, in the radial direction of said timing pulley,
so as to fit notches- provided in the buffer cylinder (50b), and tile projecting parts
are made of a material with elastic modulus which is greater than that for the elastic
body that constitutes the buffer cylinder.
9. A thermal transfer printer as claimed in Claim 5, in which said buffer means further
comprises projecting parts that are installed protrusively along the inner periphery
of tiie outer ring of said timing pulley, and the projecting parts are made of a material
with elastic modulus which is greater than that of the elastic body that constitutes
the buffer cylihder.
10. A thermal transfer printer for thermally recording information on a recording
paper, characterized by:
a platen (14) for winding the recording paper;
a thermal head (26) for thermally recording information on the recording paper;
a stepping motor (10) for intermittently turning said platen (14) via a timing belt
(18); and
a timing pulley (50) with wound timing belt (18) installed at said platen (14) for
transmitting the driving power from said stepping motor (10) to said platen
(14), said timing pulley (50) comprising an inner ring (50a), and outer ring (50c),
and a buffer cylinder (50b) which is inserted between the inner and outer rings.
11. A thermal transfer printer as claimed in Claim 10, in which said thermal head
(26) is mounted fixedly on the frame which supports said platen.
12. A thermal transfer printer as claimed in Claim 10 or 11, in which the buffer cylinder
(50b) comprises an elastic body.
13. A thermal transfer printer as claimed in Claim 12, in which a plurality of projecting
parts are installed protrusively from the inner periphery of the outer ring (50c)
of said timing pulley (50), in the radial direction of said timing pulley, so as to
fit notches provided in the buffer cylinder (50b) and the projecting parts are made
of a material with elastic modulus which is greater than that of the elastic body
that constitutes the buffer cylinder.
14. A thermal transfer printer as claimed in Claim 12, in which a plurality of projecting
parts are installed protrusivley from the outer periphery of the inner ring (50a)
of said timing pulley (50), in the radial direction of said timing pulley (50), so
as to fit notches provided in the buffer cylinder (50b), and the projecting parts
are made of a material with elastic modulus which is greater than that of the elastic
body that constitutes the buffer cylinder.
15. A thermal transfer printer as claimed in Claim 12, in which a plurality of projecting
parts are alternately installed protrusively from the inner periphery of the outer
ring (50c) and the outer periphery of the inner ring (50a) of said timing pulley,
in the radial direction of said timing pulley (50), so as to fit notches provided
in the buffer cylinder (50b), and the projecting parts are made of a material with
elastic modulus which is greater than that of the elastic body that constitutes the
buffer cylinder.
16. A thermal transfer printer as claimed in Claim 12, in which a plurality of projecting
parts are further installed along the inner periphery of the outer ring (50c) of said
timing pulley (50), and the projecting parts are made of a material with elastic modulus
which is greater than that of the elastic body that constitutes the buffer cylinder.