JP4765214B2 - Recording device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a recording apparatus in which a platen gap adjusting mechanism is connected to an end of a carriage guide shaft.
[0002]
[Prior art]
Generally, a frame notch extending in the vertical direction is formed in the side frame, and a lever member having a lever notch aligned with the frame notch is hinged to the side frame via a support pin, and passes through each notch. Then, the shaft end of the carriage guide shaft is extended, the shaft is simply connected to a platen gap adjusting mechanism having an eccentric cam and a rotating roller supported on the side frame, and the one end of the lever member and the fixing portion of the side frame are connected. A tension spring is stretched between the first pressing force that presses the carriage guide shaft against the front edge of the frame notch at the point of action formed in the lever notch, and the spring force resulting from this tension spring, and the carriage guide 2. Description of the Related Art A recording apparatus having a configuration in which an eccentric cam fixed to a shaft is distributed to a second pressing force that presses against a rotating roller is known.
[0003]
[Problems to be solved by the invention]
In this type, for example, when the platen gap is increased by the platen gap adjustment mechanism, the spring force of the tension spring is reduced, the second pressing force is reduced, and when the platen gap is reduced, the spring force of the tension spring is reduced. May increase and the second pressing force may increase. When this second pressing force increases, the pressing force between the eccentric cam fixed to the carriage guide shaft and the rotating roller increases, and smooth platen gap adjustment cannot be performed.
[0004]
Accordingly, an object of the present invention is to provide a recording apparatus that solves the above-described problems of the prior art and enables smooth platen gap adjustment regardless of the size of the platen gap.
[0005]
[Means for Solving the Problems]
According to the first aspect of the present invention, a frame notch extending in the vertical direction is formed in the side frame, and a lever member having a lever notch aligned with the frame notch is hinged to the side frame via a support pin, Extending the shaft end of the carriage guide shaft through each notch, this shaft simply connects an eccentric cam and a platen gap adjustment mechanism having a rotating roller supported by the side frame, and connects the end of the lever member to the side A tension spring is stretched between the fixed part of the frame, and the spring force resulting from this tension spring is pressed against the front edge of the frame notch at the point of action formed on the lever notch. In a recording apparatus having a configuration in which a pressing force and a second pressing force that presses an eccentric cam fixed to a carriage guide shaft against a rotating roller are distributed. Second pushing force is not the tension spring so vary according to the size of the platen gap is adjusted by a platen gap adjustment mechanism is characterized in that it is stretched.
[0006]
In the invention according to claim 2, a frame notch extending in the vertical direction is formed in the side frame, and a lever member having a lever notch aligned with the frame notch is hinged to the side frame via a support pin, Extending the shaft end of the carriage guide shaft through each notch, this shaft simply connects an eccentric cam and a platen gap adjustment mechanism having a rotating roller supported by the side frame, and connects the end of the lever member to the side A tension spring is stretched between the fixed part of the frame, and the spring force resulting from this tension spring is pressed against the front edge of the frame notch at the point of action formed on the lever notch. In a recording apparatus having a configuration in which a pressing force and a second pressing force that presses an eccentric cam fixed to a carriage guide shaft against a rotating roller are distributed. When the platen gap adjusted by the platen gap adjusting mechanism is large, the second pressing force does not change, and when the platen gap adjusted by the platen gap adjusting mechanism is small, the tension spring is tensioned so that the second pressing force decreases. It is provided.
[0007]
According to a third aspect of the present invention, when the spring force of the tension spring is S and the tangential component force is Sx, the S becomes smaller when the platen gap is large, and Sx / S. When the platen gap is small, S is increased and Sx / S is decreased.
[0008]
According to a fourth aspect of the present invention, in the device according to any one of the first to third aspects, the spring force of the tension spring is set to S, and the connection point between the tension spring and the fixing portion of the lever member is used. When the distance to the center is R1, and the distance from the action point to the center of the support pin is R2, when the platen gap is large, S is small and R1 / R2 is large, and when the platen gap is small, S is large. Thus, R1 / R2 is set to be small.
[0009]
According to a fifth aspect of the present invention, in any one of the first to fourth aspects, the spring force of the tension spring is S, the pressing force applied to the carriage guide shaft by the tension spring is G or F, and at that time When the second pressing force is Gy or Fy, when the platen gap is large, S is small and Gy / G or Fy / F is large, and when the platen gap is small, S is large and Gy / G or Fy / F. Is set to be small.
[0010]
According to a sixth aspect of the present invention, the platen gap adjusting mechanism according to any one of the first to fifth aspects includes a platen gap adjusting motor comprising a stepping motor, and the platen gap adjustment is performed when detecting the platen surface or the paper surface. Rotate the motor to store the reference pulse width, then rotate the platen gap adjustment motor to calculate the comparison pulse width, and calculate the cumulative value corresponding to the difference between the comparison pulse width and the reference pulse width. The accumulated value is compared with the contact determination reference value. When the accumulated value> contact determination reference value is reached, the count value is stored as the platen surface position or the paper surface position. The accumulated value is compared with a predetermined contact determination reference value with a value = 0, and the above steps are repeated until the accumulated value> the contact determination reference value is reached. Characterized by a run.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0012]
FIG. 1 is a perspective view showing a printer main body of a dot impact printer to which an embodiment of a recording apparatus according to the present invention is applied. FIG. 2 is a side sectional view of the printer main body of FIG.
[0013]
The printer 10 as a recording apparatus shown in these drawings prints an image including characters by hitting a number of recording wires of a recording head against a sheet via an ink ribbon (both not shown) to record dots. Dot impact printer. The printer 10 includes a printer main body 11 as a recording apparatus main body, a push tractor unit 12 attached to the printer main body 11, an upper case (not shown) and a lower case 13 that cover the upper and lower sides of the printer main body 11, respectively, And a sheet supply guide 43 that is installed on the front side of the main body 11 and guides the cut sheet K.
[0014]
The sheet includes the cut sheet K cut to a predetermined length and a continuous sheet in which a plurality of sheets are connected. Examples of the cut sheet K include cut paper, copy paper, and cut film, and examples of the continuous sheet include continuous paper.
[0015]
The printer main body 11 includes a base frame 14 as a main body frame, a main frame 15, a left side frame 16 and a right side frame 17, a recording head 18 and a carriage 19 as recording mechanisms, and a platen 20 as a sheet conveying mechanism. , A sheet guide 25, a first transport roller 21, a second transport roller 22, a third transport roller 23, and a fourth transport roller 24.
[0016]
A left side frame 16 and a right side frame 17 are erected and fixed at substantially both ends of the base frame 14 and the main frame 15. A lower carriage guide shaft 26 and an upper carriage guide shaft 27 are spanned between the left side frame 16 and the right side frame 17 at a predetermined distance in the vertical direction. Among these, the lower carriage guide shaft 26 is pivotally supported by the left side frame 16 and the right side frame 17. Further, a platen 20 is bridged between the left side frame 16 and the right side frame 17 and is rotatably disposed, and a seat guide 25 is fixedly disposed.
[0017]
The push tractor unit 12 shown in FIG. 2 supplies a continuous sheet (for example, continuous paper) to the sheet transport mechanism unit including the platen 20 and has a pair of left and right tractors 28. These tractors 28 include a tractor drive pulley (not shown) that is rotatably supported on the tractor drive shaft 29 and is slidable in the axial direction, and a tractor 28 that is rotatably supported on the tractor guide shaft 30 and slidable in the axial direction. A tractor belt 31 is wound around the tractor driven pulley (not shown) and a sheet pressing lid 32 is provided.
[0018]
The distance between the pair of tractors 28 can be adjusted according to the width dimension of the continuous sheet (continuous paper) to be conveyed. A plurality of pins 33 projecting from the entire outer periphery of the tractor belt 31 can be engaged with holes (not shown) drilled on both sides in the width direction of the continuous sheet.
[0019]
In the sheet transport mechanism including the platen 20, the first transport roller 21 and the second transport roller 22 are located on the front side of the printer main body 11, and the third transport roller 23 and the fourth transport roller 24 are connected to the printer main body. 11 is arranged on the rear side of each. Further, the first conveyance roller 21 and the second conveyance roller 22, and the third conveyance roller 23 and the fourth conveyance roller 24 are arranged in the vertical direction to make a pair.
[0020]
Among these, the first conveyance roller 21 and the third conveyance roller 23 are arranged below the sheet guide 25 together with the platen 20, and the second conveyance roller 22 and the fourth conveyance roller 24 are arranged above the sheet guide 25. The upper portions of the platen 20, the first conveyance roller 21, and the third conveyance roller 23 are in a state of protruding above the sheet guide 25. Further, a sheet holding plate 37 that holds a sheet with the sheet guide 25 is provided on the front side of the printer body 11 in the sheet guide 25.
[0021]
The platen 20, first transport roller 21, second transport roller 22, third transport roller 23, and fourth transport roller 24 are driven clockwise (CW) or counterclockwise (CCW) in FIG. Is driven to rotate. Similarly, the tractor belt 31 of the push tractor unit 12 is driven counterclockwise by the drive wheel train 34.
[0022]
The drive wheel train 34 shown in FIG. 1 is installed on one of the left side frame 16 and the right side frame 17, for example, the right side frame 17. The drive wheel train 34 includes a motor pinion 36 that is rotatably and integrally fixed to a drive shaft of a sheet supply motor 35 that can rotate forward or reverse. The driving force from the motor pinion 36 is wound around the platen 20, the first conveying roller 21, the second conveying roller 22, the third conveying roller 23, the fourth conveying roller 24, and the push tractor via a transmission mechanism and a gear mechanism. Transmission to the unit 12 is possible.
[0023]
As shown in FIG. 2, the cut sheet K such as cut sheet or copy paper is manually supplied from the front side of the printer main body 11, and then the clockwise rotation of the platen 20, the first conveyance roller 21, and the third conveyance roller 23. And the counterclockwise rotation of the second transport roller 22 and the fourth transport roller 24, the printer body 11 is transported in the direction of arrow A from the front to the rear, and the platen 20 and the first transport roller 21 are also transported. The third conveyance roller 23 is conveyed counterclockwise and the second conveyance roller 22 and the fourth conveyance roller 24 are rotated in the arrow B direction from the rear to the front of the printer body 11.
[0024]
On the other hand, a continuous sheet such as continuous paper is supplied in the direction of arrow B from the rear side of the printer main body 11 by the push tractor unit 12, and then the platen 20, the first transport roller 21, the second transport roller 22, and the third transport roller. 23 and the fourth conveying roller 24 are conveyed in the same direction (arrow B direction).
[0025]
As a result, the cut sheet K and the continuous sheet are conveyed in the sub-scanning direction orthogonal to the later-described main scanning direction of the carriage 19.
[0026]
As shown in FIG. 1, the carriage 19 is slidably inserted into the lower carriage guide shaft 26 and the upper carriage guide shaft 27 and has the recording head 18 mounted thereon. Since the lower carriage guide shaft 26 and the upper carriage guide shaft 27 are arranged in parallel with the platen 20, the carriage 19 performs main scanning that coincides with the axial directions of the platen 20, the lower carriage guide shaft 26 and the upper carriage guide shaft 27. It is provided so that it can run (scan) in the direction.
[0027]
The carriage 19 is coupled to a timing belt 39 (FIG. 2) that is reciprocated by forward rotation or reverse rotation of a carriage drive motor 38. Accordingly, the carriage 19 is guided to the lower carriage guide shaft 26 and the upper carriage guide shaft 27 via the timing belt 39 by the forward or reverse rotation of the carriage drive motor 38, and is directed leftward or rightward in FIG. 1 in the main scanning direction. Scanned. Here, the carriage drive motor 38 is configured by a stepping motor, for example, together with the sheet supply motor 35.
[0028]
As shown in FIG. 1, the carriage 19 is provided with a ribbon cassette mounting portion 40, and a ribbon cassette (both not shown) storing ink ribbons is mounted on the ribbon cassette mounting portion 40. Further, the carriage 19 is provided with a ribbon mask holder 41 that protects the ink ribbon of the ribbon cassette from a sheet (cut sheet or continuous sheet) conveyed in contact with the upper peripheral surface of the platen 20. The ink ribbon in the ribbon cassette is movably provided in front of the recording wire of the recording head 18 by a ribbon driving shaft 42 installed in the ribbon cassette mounting portion 40.
[0029]
The recording head 18 includes a large number of recording wires (not shown), and the ink ribbon is positioned in front of the protruding direction of these recording wires as described above. While the recording head 18 is scanned in the main scanning direction together with the carriage 19, the recording wire protrudes and strikes the ink ribbon. The ink on the ink ribbon is placed between the platen 20 (FIG. 2) and the recording head 18. Attached to a sheet (cut sheet K or continuous sheet) conveyed on the sheet, an image including characters is recorded on the sheet.
[0030]
In the recording operation by the recording head 18, one line sentence is recorded by the recording wire of the recording head 18 while the carriage 19 is scanned leftward or rightward in the main scanning direction, and the sheet is recorded each time the one line sentence is recorded. Is a cut sheet K, the sheet transport mechanism (platen 20, first transport roller 21, second transport roller 22, third transport roller 23, and fourth transport roller 24), and the sheet is a continuous sheet In this case, the sheet conveying mechanism and the push tractor unit 12 convey the sheet by a predetermined length (for an interval between normal rows) and repeat these operations. The carriage drive motor 38 shown in FIG. 1 is installed and supported on a substantially box-shaped motor mounting bracket 44 fixed to the right side frame 17.
[0031]
2 and 3, the printer 10 moves the lower carriage guide shaft 26 toward the platen 20 by rotating the lower carriage guide shaft 26, and moves the carriage 19 relative to the platen 20. A platen gap adjusting mechanism 45 that moves in the vertical direction and adjusts the platen gap between the recording head 18 mounted on the carriage 19 and the platen 20 according to the sheet thickness is provided. At this time, the upper carriage guide shaft 27 fits and supports the carriage 19 so as to be movable in the direction perpendicular to the platen 20, and thus the movement of the carriage 19 is not restricted.
[0032]
The platen gap adjusting mechanism 45 is connected to both ends of the lower carriage guide shaft 26, FIG. 4 shows the right side frame 17 side, and FIG. 7 shows the left frame 16 side. As shown in FIGS. 4 and 7, the platen gap adjusting mechanism 45 includes an eccentric cam 46, a rotating roller 47, lever members 48 and 58, a platen gap adjusting motor 49, an output gear 50, and reduction gears 51, 52 and 53. It is comprised.
[0033]
The eccentric cam 46 is rotatably and integrally fixed to both ends of the lower carriage guide shaft 26. The eccentric cam 46 has a substantially semicircular shape as shown in FIGS. 5 and 8 and is configured such that the radius of the outer peripheral surface 54 gradually changes. For example, if the radii at both ends are Ra and Rc, and the central radius is Rb, then Ra>Rb> Rc. An outer peripheral surface 54 of the eccentric cam 46 is provided so as to be able to contact the rotating roller 47 that is rotatably supported by the left side frame 16 and the right side frame 17.
[0034]
Here, as shown in FIGS. 6 and 9, both end portions of the lower carriage guide shaft 26 are inserted into frame cutouts 55 and 56 formed in the left side frame 16 and the right side frame 17, respectively, so as to be lever members. The lever notch 62 of the lever 48 and the lever notch 63 of the lever member 58 (both will be described later) are inserted, and the eccentric cam 46 is fixed to the outside thereof. The frame notches 55 and 56 include front edges 55A and 56A formed in a direction perpendicular to the platen 20, respectively. Further, as shown in FIGS. 7 and 8, the eccentric cam 46 is rotationally integrated with the lower carriage guide shaft 26 by using a mounting screw 57.
[0035]
As shown in FIGS. 4 to 6, the lever member 58 has a base portion 58 </ b> A attached to the right side frame 17 using a support pin 59 so as to be rotatable. A tension spring 66 is interposed between the standing portion 58B of the lever member 58 and the locking portion 60 suspended from the right side frame 17. The tension spring 66 gives the lever member 58 a force that rotates around the support pin 59 in the direction of arrow M in FIGS.
[0036]
A lever notch 63 is formed in the base member 58 </ b> A in the lever member 58, and one end of the lower carriage guide shaft 26 is inserted into the lever notch 63. The lever notch 63 has an action point 65 on the support pin 59 side. The action point 65 of the lever member 58 applies a pressing force F to the lower carriage guide shaft 26 when the turning force in the direction of arrow M is applied to the lever member 58 by the tensile force of the tension spring 66. The component force Fx of the pressing force F constantly presses the lower carriage guide shaft 26 against the front edge 56A of the frame notch 56, and the component force Fy of the pressing force F causes the eccentric cam 46 fixed to the lower carriage guide shaft 26 to move. Always pressed against the rotating roller 47.
[0037]
Therefore, one end of the lower carriage guide shaft 26 is sandwiched between the operating point 65 of the lever member 58 and the front edge 56A of the frame notch 56 of the right side frame 17.
[0038]
Further, as shown in FIGS. 8 and 9, the lever member 48 is attached to the left side frame 16 so that its base portion 48 </ b> A can be rotated using a support pin 59. A tension spring 61 is interposed between the standing portion 48B of the lever member 48 and a locking portion (not shown) suspended from the left side frame 16. The tension spring 61 gives the lever member 48 a force that rotates around the support pin 59 in the direction of arrow N in FIGS.
[0039]
A lever notch 62 is formed in the base member 48 </ b> A in the lever member 48, and the other end portion of the lower carriage guide shaft 26 is inserted into the lever notch 62. The lever notch 62 has an action point 64 on the support pin 59 side. The action point 64 of the lever member 48 applies a pressing force G to the lower carriage guide shaft 26 when the turning force in the direction of arrow N is applied to the lever member 48 by the tensile force of the tension spring 61. The component force Gx of the pressing force G constantly presses the lower carriage guide shaft 26 against the front edge 55A of the frame notch 55, and the component force Gy of the pressing force G causes the eccentric cam 46 fixed to the lower carriage guide shaft 26 to move. Always pressed against the rotating roller 47.
[0040]
For this reason, the other end portion of the lower carriage guide shaft 26 is sandwiched between the operating point 64 of the lever member 48 and the front edge 55A of the frame notch 55 of the left side frame 16.
[0041]
The platen gap adjusting motor 49 is fixed to the left side frame 16 as shown in FIGS. 7 and 8, and the output gear 50 is integrally fixed to the output shaft. The reduction gear 51 meshes with the output gear 50. The reduction gear 52 is formed integrally with the reduction gear 51 and meshes with the reduction gear 53. The reduction gear 53 is fixed to the other end of the lower carriage guide shaft 26 so as to rotate together.
[0042]
Accordingly, the driving force of the platen gap adjusting motor 49 is transmitted to the lower carriage guide shaft 26 via the output gear 50 and the reduction gears 51, 52 and 53, and the lower carriage guide shaft 26 rotates. At this time, the outer peripheral surface 54 of the eccentric cam 46 is always pressed by the rotating roller 47, and the lower carriage guide shaft 26 is always pressed by the front edge 55A of the frame notch 55 and the front edge 56A of the frame notch 56. As the lower carriage guide shaft 26 rotates, the lower carriage guide shaft 26 moves in the direction perpendicular to the platen 20 along the front edges 55A and 56A by an amount corresponding to the radius difference of the eccentric cam 46. As a result, the recording head 18 is brought into contact with and separated from the platen 20 via the carriage 19, and the platen gap is adjusted within a range of, for example, 3 mm at the maximum.
[0043]
In this embodiment, referring to FIG. 6, a frame notch 56 extending in the vertical direction is formed in the right side frame 17, and a lever member 58 having a lever notch 63 aligned with the frame notch 56 is used as a support pin. 59 is connected to the right side frame 17 through a hinge 59, extends through the notches 56 and 63, and extends the shaft end of the carriage guide shaft 26. This shaft is simply an eccentric cam, a rotating roller supported by the right side frame, etc. The platen gap adjusting mechanism 45 having the above is connected, and a tension spring 66 is stretched between one end 58B of the lever member 58 and the fixing portion of the right side frame 17, and the spring force F by the tension spring 66 is applied to the lever cutting mechanism. The first pressing force Fx that presses the carriage guide shaft 26 against the front edge 56A of the frame notch 56 at the action point 65 formed in the notch 63, and the carriage guide And a structure for dispersing into the second pressing force Fy that presses the eccentric cam fixed to de shaft 26 to rotate the roller.
[0044]
First If it is difficult to adjust so that the double pressing force Fy does not fluctuate, in the stage of adjusting the platen gap, if the platen gap is large, the second pressing force Fy does not fluctuate and maintains a substantially constant value. When the platen gap is small, it is desirable to stretch the tension spring 66 so that the second pressing force Fy decreases.
[0045]
The spring force of the tension spring 66 is S, the tangential component force is Sx, the distance from the connection point A between the tension spring 66 and the fixing portion 58B of the lever member 58 to the center of the support pin 59 is R1, and the action point When the distance from 65 to the center of the support pin 59 is R2, the pressing force that the tension spring 66 applies to the carriage guide shaft 26 is F, and the second pressing force at that time is Fy, when the platen gap is large, S The value decreases and the values of Sx / S, R1 / R2, and Fy / F increase, and when the platen gap is small, the value of S increases and the values of Sx / S, R1 / R2, and Fy / F decrease. It is desirable to set as follows.
[0046]
On the left side frame 16 side, as shown in FIG. 9, a tension spring 61 is stretched. In this case, as in the case shown in FIG. 6, when the platen gap is large, the value of S is small. Sx / S, R1 / R2, and Gy / G are increased, and when the platen gap is small, S is increased and Sx / S, R1 / R2, and Gy / G are decreased. Is done.
[0047]
In this type, as shown in FIGS. 4 to 6 and FIGS. 7 to 9, when the position corresponding to the radius Rb on the outer peripheral surface 54 of the eccentric cam 46 is in contact with the rotating roller 47, the platen gap is medium. Set to
[0048]
As shown in FIGS. 10 to 13, when the position corresponding to the radius Rc on the outer peripheral surface 54 of the eccentric cam 46 is in contact with the rotary roller 47, the platen gap is set wide, and the spring force of the tension springs 61 and 66 is small. Become. Further, as shown in FIGS. 14 to 17, when the position corresponding to the radius Ra on the outer peripheral surface 54 of the eccentric cam 46 is in contact with the rotating roller 47, the platen gap is set narrow, and the spring force of the tension springs 61 and 66 is set. Will grow.
[0049]
In the present embodiment, since each of the tension springs 61 and 66 is stretched as described above, even if the spring force of the tension springs 61 and 66 varies, the second pressing forces Fy and Gy Is The Be Therefore, smooth platen gap adjustment can be performed regardless of the size of the platen gap.
[0050]
Further, when adjusting the platen gap, the lower carriage guide shaft 26 moves along the front edge 55A of the frame notch 55 and the front edge 56A of the frame notch 56 only in the direction perpendicular to the platen 20, and moves in the front-rear direction of the printer 10. do not do. For this reason, since the recording head 18 of the carriage 19 inserted through the lower carriage guide shaft 26 is held at an appropriate position with respect to the apex of the platen 20, good recording is ensured by the recording head 18.
[0051]
Next, the procedure for adjusting the platen gap will be described.
[0052]
Although not shown, the platen gap adjusting mechanism 45 is provided with a rotary encoder, and the rotation angle of the platen gap adjusting motor (stepping motor) 49 is detected by the rotary encoder.
[0053]
The rotary encoder includes a slit plate (not shown) that is provided integrally with the output shaft of the platen gap adjusting motor 49 and has the same number of slits as the number of poles of the motor 49 (for example, 48 poles). For example, it includes a light projecting / receiving device (not shown) made of a light emitting diode, a photodiode, or the like, which is disposed to face the slit plate. The light emitted from the light emitting diode of the light emitter / receiver and passed through the slit of the slit plate is received by the photodiode of the light emitter / receiver and converted into a pulse wave. By counting this pulse wave, the platen gap adjusting motor 49 rotation angles are detected.
[0054]
By driving the gap adjusting motor 49, the platen gap is lowered to bring the recording head at the measurement reference position into contact with the platen surface or the paper surface. The paper thickness is obtained by subtracting the distance until contact, and the gap adjusting motor 49 is driven and adjusted according to the paper thickness. However, in order to prevent damage or the like when the recording head is brought into strong contact with the platen surface or the paper surface, the platen gap adjustment here is performed by detection before the step-out of the motor 49.
[0055]
As shown in FIGS. 18 and 19, the platen gap adjusting motor 49 is driven to move the recording head to the measurement reference position (S1). Next, in the case of platen surface detection, the recording paper is discharged from the platen surface. In the case of paper surface detection, the recording paper is fed to the platen surface (S2), and the platen gap adjustment motor 49 is turned on. After being idle (S3), the reference pulse width is stored (S4).
[0056]
FIG. 20 shows a storage flow of the reference pulse width. That is, the motor 49 is rotated by one pulse (S11), and the time T related to the pulse width output from the rotary encoder as shown in FIG. _i Is detected (S12).
[0057]
Next, the accumulated value U of the detection method before step-out (ring buffer method), which will be described later, due to the influence of the characteristics of the platen gap adjusting motor (stepping motor). _b In order to reduce the fluctuation of the value, 4 addition value is used and the reference pulse width is set to S _a As S _a = T _i-3 + T _i-2 + T _i-1 + T _i S corresponding to the number of poles 48 of the motor 49 is calculated. ₁ ~ S ₄₈ Are sequentially stored (S13). However, since a = i−3, i = 51 when a = 48. This reference pulse width S _a Then, the process proceeds to S5 in FIG. 18 where platen surface or paper surface detection is started, and after this is started, contact position determination is performed (S6).
[0058]
FIG. 22 shows the contact position determination. The motor 49 is rotated by one pulse (S15), and the time T related to the pulse width output from the rotary encoder. _i Is detected (S16). Then, b = i−3 and the comparison pulse width is S _b As S _b = T _i-3 + T _i-2 + T _i-1 + T _i (S17), n satisfying the following expression (1) is obtained, and the value of a at that time is calculated (S18). Here, n and a are integers, and since i ≧ 52, b ≧ 49.
[0059]
1 ≦ a = (b / 48−n) × 48 ≦ 48 (1)
For example, when i = 100, since b = i−3 = 97, if these are substituted into the equation (1), 1 ≦ a = (97 / 48−n) × 48 ≦ 48, n, a The combination is n = 2 and a = 1.
[0060]
Next, the difference Δtb = S from the reference pulse width Sa _b -S _a (S19), the difference is added, and the accumulated value U _b = U _b-1 + Δtb is calculated (S20). For example, when i = 100, as described above, since b = 97 and a = 1, Δt ₉₇ = S ₉₇ -S ₁ And U ₉₇ = U ₉₆ + Δt ₉₇ It becomes.
[0061]
This accumulated value U _b An example of this is shown in FIG. And the cumulative value U _b Is compared with an appropriately set contact determination reference value (S21), U _b <If the contact determination reference value, the process proceeds to S15 and the above steps are repeated. _b When the contact determination reference value is reached, the count value is stored as the platen surface position or the paper surface position (S22), and the process proceeds to S7 in FIG. 18 to complete the platen surface or paper surface detection. By appropriately setting the contact determination reference value, detection before step-out can be performed.
[0062]
Then, the paper thickness is detected by subtracting the distance from the measurement reference position of S1 to the platen surface and the distance from the measurement reference position to the paper surface, and the motor 49 is driven in accordance with the paper thickness to set the platen gap. Adjusted.
[0063]
In S20, U _b <0, U _b = 0 and this U _b Is compared with a predetermined contact determination reference value (S21), and the following steps are repeated.
[0064]
In the present embodiment, at the stage of adjusting the platen gap by the platen gap adjusting mechanism 45, as shown in FIG. 23, when the platen gap is large, the second pressing forces Fy and Gy do not change as indicated by the arrow A. When the platen gap is small and the platen gap is small, the tension springs 66 and 61 can be stretched so that the second pressing forces Fy and Gy decrease as indicated by an arrow B.
[0065]
When the tension springs 66 and 61 are tensioned in this way, the second pressing forces Fy and Gy do not increase when the platen gap is adjusted, and the pressing force between the eccentric cam fixed to the carriage guide shaft 26 and the rotating roller. The platen gap is always adjusted smoothly without increasing.
[0066]
Further, since an increase in the load on the platen gap adjusting motor due to an increase in the pressing force between the eccentric cam and the rotating roller is suppressed, U in FIG. _b Cumulative value U as shown by ′ _b Can be suppressed, and the detection accuracy of the paper thickness calculated from the difference between the detection count values of the platen surface and the paper surface can be improved.
[0067]
However, in this case, as the platen gap decreases, the second pressing forces Fy and Gy decrease. _b There is a risk of <0.
[0068]
In this embodiment, the cumulative value U _b Even if <0, this is U _b = 0 and this cumulative value U _b Since = 0 is compared with a predetermined contact determination reference value (S21), the following steps are repeated, so that the platen gap adjustment by the pre-step-out detection method (ring buffer method) can be executed reliably.
[0069]
As mentioned above, although this invention was demonstrated based on the said embodiment, this invention is not limited to this.
[0070]
【The invention's effect】
In the present invention, smooth platen gap adjustment can be performed regardless of the size of the platen gap.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a printer main body of a dot impact printer to which an embodiment of a recording apparatus according to the invention is applied.
FIG. 2 is a side sectional view showing the printer main body of FIG.
FIG. 3 is a perspective view showing the platen gap adjusting mechanism of FIG. 1 together with a side frame.
4 is an enlarged perspective view showing a part of a right side frame and a platen gap adjusting mechanism in FIG. 3; FIG.
5 is a front view showing a part of the platen gap adjusting mechanism (a state in which the platen gap is intermediate) in FIG. 4 and the like. FIG.
6 is a front view showing a part of the platen gap adjusting mechanism (a state in which the platen gap is intermediate) in FIG. 5 excluding the eccentric cam. FIG.
7 is an enlarged perspective view showing the other part of the left side frame and the platen gap adjusting mechanism of FIG. 3; FIG.
8 is a front view showing the other part and the like of the platen gap adjusting mechanism (the platen gap is in an intermediate state) shown in FIG. 7;
9 is a front view showing the other part of the platen gap adjusting mechanism of FIG. 8 excluding the eccentric cam and various gears. FIG.
10 is a front view showing a part of the platen gap adjusting mechanism in FIG. 5 when the platen gap is set wide.
11 is a front view showing a part of the platen gap adjusting mechanism of FIG. 10 excluding an eccentric cam. FIG.
12 is a front view showing the other part of the platen gap adjustment mechanism in FIG. 8 when the platen gap is set wide.
13 is a front view showing the other part of the platen gap adjusting mechanism of FIG. 12, excluding the eccentric cam and various gears. FIG.
14 is a front view showing a part of the platen gap adjusting mechanism in FIG. 5 when the platen gap is set narrow. FIG.
15 is a front view showing a part of the platen gap adjusting mechanism of FIG. 14 excluding an eccentric cam and various gears.
16 is a front view showing the other part and the like of the platen gap adjusting mechanism in FIG. 8 when the platen gap is set narrow.
17 is a front view showing the other part of the platen gap adjusting mechanism of FIG. 16, excluding the eccentric cam and various gears.
FIG. 18 is a flowchart of platen surface or paper surface detection.
FIG. 19 is a time chart of platen surface or paper surface detection.
FIG. 20 is a flowchart of storing a reference pulse width.
FIG. 21 is a time chart when a reference pulse width is stored.
FIG. 22 is a flowchart of contact position determination.
FIG. 23 is a diagram illustrating a relationship between a platen gap and a second pressing force.
FIG. 24: Cumulative value U _b It is a figure which shows an example.
[Explanation of symbols]
10 printers (recording devices)
16 Left side frame
17 Right side frame
18 Recording head
19 Carriage
26 Lower carriage guide shaft
45 Platen gap adjustment mechanism
46 Eccentric cam
47 Rotating roller
48 Lever member
55, 56 frame cutout
55A, 56A Frame notch front edge
58 Lever member
61 Tension spring
62, 63 Lever notch
64, 65 Lever notch action point
66 Tension spring
Fx first pressing force
Fy second pressing force
S Spring force

Claims (2)

A frame notch extending in the vertical direction is formed in the side frame, and a lever member having a lever notch aligned with the frame notch is hinged to the side frame via a support pin, and passes through each notch. A platen gap adjusting mechanism having a shaft end of the carriage guide shaft extending and having an eccentric cam and a rotating roller supported by the side frame is connected to the shaft end, and between the one end of the lever member and the fixing portion of the side frame. A tension spring is stretched on the lever , and the pressing force G, F applied to the carriage guide shaft due to the spring force of the tension spring is applied at the point of action formed in the lever notch. dispersing the first pushing force Gx pressed against the edge, and Fx, the second pushing force Gy for pressing the eccentric cam fixed to the carriage guide shaft to the rotating roller, to the Fy In the recording apparatus having a configuration in which,
The angle between the line perpendicular to the line connecting one end of the lever member and the support pin and passing through one end of the lever member and the line along the direction of the spring force S of the tension spring increases the platen gap. Then becomes smaller, Ri name larger when the platen gap is reduced,
When the platen gap is enlarged, S is decreased, and the lever member is rotated to displace the action point, whereby the distance from the connection point between the tension spring and the fixed portion of the lever member to the center of the support pin. R1 / R2 increases for R1 and the distance R2 from the point of action to the center of the support pin, and Gy / G or Fy / F increases.
When the platen gap is reduced, S is increased, the lever member is pivoted becomes small R1 / R2 by the action point is displaced, the tensile so that a small Gy / G or Fy / F spring Is stretched. The platen gap adjustment mechanism is equipped with a platen gap adjustment motor consisting of a stepping motor. When detecting the platen surface or paper surface, the platen gap adjustment motor is rotated to store the reference pulse width, and then the platen gap adjustment motor is rotated. A comparison pulse width is calculated, a cumulative value corresponding to the difference between the comparison pulse width and the reference pulse width is calculated, the cumulative value is compared with the contact determination reference value, and cumulative value> contact determination reference When reaching the value, the count value is stored as the platen surface position or the paper surface position, and when the accumulated value <0, the accumulated value = 0 is compared with a predetermined contact determination reference value, and the accumulated value> abutment judgment until it reaches the reference value and executes a control to repeat the above steps according to claim 1 Symbol placement of the recording apparatus.

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