JPH10138608A - Recording apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To form a recording apparatus provided with a line recording mode and a serial recording mode at low manufacturing cost, which can be used facilely. SOLUTION: A tape printing device has a line recording mode for recording on a first medium to be recorded in use of an ink ribbon IR in a state of a fixed recording head HD and a serial recording mode for recording with the use of the ink ribbon IR with respect to a second recording medium to be recorded while carrying the recording head HD in the scanning direction. The detecting sensor detects a cassette TC used during the period of a line recording mode and a cassette RC used during the period of a serial recording mode, and further the control device determines whether or not the detected effects are in agreement with a command of the line recording mode and a command of the serial recording mode.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording apparatus for recording characters and marks such as characters on a recording medium,
In particular, it has both a line recording mode in which recording is performed while the first recording medium is conveyed while the recording head is fixed, and a serial recording mode in which recording is performed while the recording head scans the second recording medium. It relates to a recording device.

[0002]

2. Description of the Related Art The applicant of the present invention has proposed and put to practical use a tape-shaped label producing apparatus as an example of a recording apparatus. The apparatus is disclosed in Japanese Patent Application Laid-Open No. 5-84994. As described, it has a keyboard, a display, and a recording mechanism of the thermal recording method.The thermal head records the characters and marks of the input text on the recording tape via the ink ribbon, and prints them on the spine of the file. A label suitable for application can be created.

[0003] A label made of the recording tape can record characters and marks in various character sizes and typefaces, for example, in tape widths of 6, 9, 12, 18, and 24 mm. Things have become desirable. The tape-shaped label is not limited to the spine of the file. For example, a label having a wider width or a color-recording label is desired for a guide board as a display or a price card for a store. It became so.

However, in a so-called line recording system in which a recording head is fixed and a recording tape is conveyed, if the tape is wide, the recording head needs to be as wide as the recording width, resulting in an increase in cost. There is.

Conventionally, as described in JP-A-7-117297, there are a line recording mode in which a recording head is fixed and recording is performed on recording paper, and a serial recording mode in which recording is performed while scanning the recording head. In the recording apparatus, the recording head performs line recording for small-sized recording paper, while rotating the recording head 90 degrees in the transport direction of the recording paper for large-sized recording paper. Thus, serial recording can be performed. However, such a rotating mechanism of the recording head may increase the size of the apparatus and increase the manufacturing cost.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem, and a fixed recording head can perform recording on a first recording medium in a line recording mode. It is an object of the present invention to provide a recording apparatus that performs reciprocal scanning on a second recording medium in the main scanning direction and performs recording in a serial recording mode with good usability and low manufacturing cost.

[0007]

According to a first aspect of the present invention, there is provided a recording apparatus comprising: a recording head; and a head conveying means for reciprocating the recording head in a main scanning direction. A line recording mode in which recording is performed on a first recording medium using a first ink medium while the recording head is fixed, and a line recording mode in which the recording head is conveyed in the main scanning direction. In a recording apparatus having a serial recording mode for performing recording using a second ink medium on a second recording medium, the first recording medium or the first recording medium used in the line recording mode is used.
At least one of the ink media, or
At least one of the second recording medium and the second ink medium used in the serial recording mode is detected, and the detection result matches the line recording mode command and the serial recording mode command. A determination means for determining whether or not the determination is made;

Accordingly, the fixed recording head can perform recording in the line recording mode using the first ink medium on the first recording medium, whereas it can perform recording on the second recording medium. In other words, the recording head reciprocates in the main scanning direction of the second recording medium without using a rotating mechanism as in the prior art, and uses the second ink medium to perform the second recording medium. Can be recorded in the serial recording mode. In that case, the determination means may be at least one of the first recording medium or the first ink medium used in the line recording mode, or the second recording medium or the second recording medium used in the serial recording mode. At least one of the two ink media is detected, and it is determined whether or not the detection result matches the line recording mode command and the serial recording mode command. Therefore, for example, the first recording medium or the first ink medium is
There is no erroneous use in the serial recording mode, and no erroneous use of the second recording medium or the second ink medium in the line recording mode.

According to the recording apparatus of the present invention, in the line recording mode, at least the first cassette accommodating the first recording medium is used, and in the serial recording mode, the second cassette is used. A second cassette containing only ink media is used. In this case, the second cassette does not store the recording medium and is compact. It is desirable that the second cassette is different from the first cassette in the location where the ink ribbon is disposed inside.

[0010] According to the recording apparatus of the third aspect, the first cassette further stores the first ink medium. As described above, when the first ink medium is stored in the first cassette, the handling is easier than when the first ink medium is not stored.

Further, according to the recording apparatus of the present invention, there is provided a detecting device for discriminating between the first cassette and the second cassette. The determining means determines whether or not the mode command matches. Therefore, for example, the first cassette is not erroneously used in the serial recording mode, and the second cassette is not erroneously used in the line recording mode.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, a recording apparatus according to the present embodiment is a tape printing apparatus 1 that prints a large number of characters or marks such as hiragana, kanji, and symbols on a wide or narrow recording medium (tape). It is. Inside the tape printer 1, a tape station TS for recording a narrow recording medium D1 as a first recording medium in a single color, and a wide recording medium D2 as a second recording medium. And a wide station WS for recording the image in either color or monochrome. Thereby, after the recording is completed, the narrow recording target recorded in monochromatic at the tape station TS from an outlet (not shown) on one side (left side) of the main body frame 2 of the tape printing apparatus 1 at the tape station TS. While the medium D1 is ejected, a wide recording medium D2 recorded in color or monochrome in the wide station WS is ejected from an ejection port 2a at the center of the front surface of the main body frame 2.

On the keyboard 3, in addition to a plurality of character keys and mark keys for inputting characters such as a line feed key and hiragana, various keys, for example, a recording execution key of the tape station TS or a wide key. Editing keys such as a recording execution key and a cancel key of the station WS, and setting keys for vertical writing or horizontal writing are provided.
When a cable 4 is connected between the tape printer 1 and the keyboard 3, signals such as data input through various keys on the keyboard 3 are transmitted and received via the cable 4. Can be. A display 5 as a display device is provided on the front right side of the main body frame 2. The display 5 displays characters and marks input from the keyboard 3 over a plurality of lines on the screen. Can be displayed.

On the front side of the main body frame 2, a cover case 7 which is openable and closable on the near side is provided.
The cover case 7 is opened, and either the tape cassette TC or the color or single-color ribbon cassette RC used at the time of the wide station WS is loaded into the carriage CA.
The cover case 7 can be closed by setting on the top. Thereby, depending on whether the user desires the narrow recording medium D1 recorded in a single color or the wide recording medium D2 recorded in a color or a single color,
Either the tape cassette TC or the ribbon cassette RC is selected, and the carriage CA in the cover case 7 is selected.
Can be set on top. In the tape printing apparatus 1 of the present embodiment, in the tape station TS, recording can be performed only on the narrow recording medium D1 in a single color, but is not necessarily limited to this mode, and full-color recording can be performed. It may be changed as follows.

FIGS. 2 and 3 are a front view and a plan view, respectively, showing a main part of a recording mechanism inside the tape printing apparatus 1 according to the present embodiment. The tape station TS refers to a recording area on the left side of the bottom chassis HS extending forward and backward inside the main body frame 2 shown in FIGS. 2 and 3, and the wide station WS refers to the recording area of the bottom chassis HS. Refers to the right recording area. In the tape station TS, recording is performed in the line recording mode. In the line recording mode, the narrow recording medium D1 pulled out from the tape cassette TC and the ink ribbon IR or the like used for recording on the recording medium D1 are moved in one direction, that is, in the main body frame 2. It is transported to the outside of the side. Then, the recording head HD in a fixed state performs recording on the narrow recording medium D1 via the ink ribbon IR,
Only the recorded recording medium D1 is discharged to the outside of the side of the main body frame 2.

On the other hand, in the wide station WS,
Recording is performed in the serial recording mode. In this serial recording mode, the recording head HD is transported in the main scanning direction (ie, the horizontal direction in FIGS. 2 and 3) that intersects the transport direction of the wide recording medium D2 (ie, the direction from the top to the bottom in FIG. 3). While the recording head HD performs recording on the recording medium D2, after the recording is completed, the recording medium D2 is transported by a predetermined amount in the transport direction, and is again recorded while transported in the main scanning direction.

Specifically, the carriage transport mechanism CH
FIG. 4B shows a state in which the carriage CA is reciprocated in the main scanning direction that intersects with the direction in which the wide recording medium D2 is conveyed.
As shown in the figure, the recording head HD performs recording in the main scanning direction of the recording medium D2 ("A", "I"
"U", "E", "O" lines, and "KA""KI""KU"
At the same time, after the recording is completed, the transport mechanism QH for the wide recording medium D2 moves the recording medium D2 by a predetermined amount (a large number of heating elements) in the transport direction from top to bottom in FIG. (See FIG. 4A)). Then, by the carriage transport mechanism CH transporting the carriage CA again in the main scanning direction of the recording medium D2, the recording head HD records on the recording medium D2 (as shown in FIG. 2). “Set” and “so” are recorded), and the same manner is repeated.

The carriage transport mechanism CH includes a step motor SM installed at the right end inside the main body frame 2.
, A small-diameter drive gear portion SM2 attached so as to mesh with the drive shaft SM1 of the motor SM, and a large-diameter drive gear portion SM3 meshed with the gear portion SM2 (FIG. 3).
), A driving pulley SP2 for the timing belt that rotates integrally with the gear portion SM3, a driven pulley SP1 for the timing belt provided at the left end inside the main body frame 2, and both pulleys SP1, A guide for supporting the carriage CA that extends between the SP2 and the rear end CA1 of the carriage CA and that is connected to the rear end CA1 of the carriage CA and that extends through the rear end support portion CA2 of the carriage CA and extends inside the main body frame 2. Axis GD.

When the stepping motor SM is driven forward or backward, the driving pulley SP2 is rotated in one direction or the opposite direction via the driving shaft SM1 and the driving gears SM2 and SM3, and the timing belt TB is rotated in one direction. Move in or out direction. Therefore, with the movement of the timing belt TB, the carriage CA on which the recording head HD is mounted can move between the two pulleys SP1 and SP2 along the guide axis GD without using a head rotating mechanism as in the related art. 2 and 3, the tape is fed stepwise in the left-right direction, so that it is arranged at the tape station TS as shown by the solid line in FIGS.
As shown by the two-dot chain line, the wide station WS
Reciprocate in the recording area. The step motor S
Since the control pulse amount of M and the feed amount of the timing belt TB accurately correspond to each other, if the control device CP shown in FIG. The TB is fed by a predetermined amount, and the carriage CA is accurately conveyed.

The transport mechanism QH for the wide recording medium D2
Are supporting projections ST1, ST2 for supporting a wound recording medium D2 placed on the rear side inside the main body frame 2.
And paper feed roller units JR1 and JR2 arranged side by side at a predetermined distance in that order in the main scanning direction of the recording medium D2.
And

Specifically, between the chassis KS and the long side chassis HS2, support projections ST2 and ST1 are attached to the chassis KS and the long side chassis HS2, respectively. Is inserted from both sides into the central space D2a of the wound recording medium D2 to support the medium D2 (see FIG. 4). Incidentally, the cassette case HS0 as shown by the two-dot chain line in FIG.
However, it is desirable to store the recording medium D2 in the wound state, but it is not necessarily limited to that mode.

In this case, a compression spring AB is attached to the support projection ST1 on the bottom chassis HS side so as to bias the projection ST1 toward the chassis KS. On the other hand, the support projection ST2 on the chassis KS side
Is movable toward the support projection ST1 on the bottom chassis HS side so as to correspond to the sheet width of the recording medium D2, and is indicated by, for example, a solid line or a two-dot chain line in FIG. As described above, even if the recording medium D2 has a different sheet width, the two support projections ST1 and ST2 are not connected to the recording medium D2.
2, the leading end side of the recording medium D2 can be sent out in the direction of the sheet feed rollers JR1 and JR2.

The rollers JR1 and JR2 are rotatably mounted between the long side chassis HS2 in the bottom side chassis HS and the chassis KS on the wide station WS side. The bottom chassis H
Tape station TS of short side chassis HS1 in S
On the side, a step motor SN is fixed. Therefore, the driving force of the forward or reverse rotation of the motor SN is applied to the gears Y1 to Y7, ST3, ST3, which constitute the sheet feeding gear train GY arranged side by side along the long side chassis HS2.
The transmission via ST4 and the like causes the support projection ST1 and the roller portions JR1 and JR2 to rotate clockwise or counterclockwise.

The roller portions JR1 and JR2 have a plurality of sheet feed rollers JR1b and JR2b attached to a pair of upper and lower roller shafts JR1a and JR2a, respectively. Therefore, when the rollers JR1b and JR2b are pressed against each other and the leading end of the wound recording medium D2 is sandwiched between the rollers JR1b and JR2b, and the rollers JR1b and JR2b rotate, the recording is performed. The medium D2 is conveyed forward so as to be pulled out, or conveyed backward so as to be rewound.

Further, a second platen P2 is provided on the bottom surface side of the recording head HD between the paper feed roller portions JR1 and JR2 through which the recording medium D2 is supported. It is formed in a substantially flat shape. In this case, if a cylindrical platen is used as the second platen P2, the heating element for recording on the recording head HD is orthogonal to the cylindrical platen. Without sufficient pressure contact with the platen, the recording result is likely to be blurred or missing.
Accordingly, if the second platen P2 is formed in a substantially flat plate shape, such a situation can be prevented. Therefore, it is desirable to use a flat platen rather than a cylindrical platen.

A sensor mark SX is provided on the upper surface on the side (left side in FIG. 3) of the platen P2. The mark SX is used when the recording head HD reciprocates in the left-right direction. Head H on the side
It is used to detect the moving origin of D. That is, when the control device CP sends a control pulse to the step motor SM by a predetermined amount to cause the recording head HD to perform recording while moving forward in the main scanning direction, the movement origin on the wide station WS side by the mark SX is recorded. This serves as a reference for controlling the position of the head HD.

More specifically, the mark SX has two patterns having a reflection area and a non-reflection area alternately. A reflection sensor (not shown) mounted on the carriage CA is mounted on the platen P2. The mark SX as a target attached to the target is detected. Then, the control device CP determines the position at which the reflection sensor detects a change point where the reflection state changes from the reflection state to the non-reflection state twice, as the origin. This is because if there is only one change point, and if there is a white recording medium D2 with respect to the black platen, the control device CP mistakenly detects the boundary between the sheet and the platen as the change point. . To prevent such false detections,
It is desirable to provide the sensor mark SX having two patterns as described above.

Further, a detection sensor SW for detecting the leading end of the recording medium D2 is provided near the downstream side of the roller portion JR2, and the conveyance of the recording medium D2 is performed based on the output signal of the sensor SW. Control is performed. For example, the user sets the recording medium D2 at a predetermined position on the rear side inside the main body frame 2 and sets the leading end side to the sheet feed roller unit J.
The sheet is fed in the R1 and JR2 directions, and the sheet can be fed. Then, the forward rotation drive of the step motor SN is transmitted through the gear train GY, and the both rollers JR are transmitted.
1. The controller CP drives the step motor SN until the sensor SW detects the leading end of the recording medium D2.
Since the control pulse amount of the step motor SN and the feed amount of the recording medium D2 correspond exactly unless there is a feed error such as meandering, the control device CP controls the step motor SN to perform the control. When the pulse is sent by a predetermined amount, the conveyance control of the recording medium D2 is performed.

Further, a cutter device KC for cutting the recording medium D2 is provided downstream of the roller portion JR2, and the cutter device KC operates under a predetermined control under the conveyance control of the recording medium D2. By operating at the timing,
The recording medium D2 is cut. The cutter device KC may be of a type in which, for example, the blade portion KC1 of the cutter (see FIG. 4) reciprocates in the width direction of the recording medium D2 (the left-right direction in FIG. 3) and cuts. , Other than that, blade part KC
The one blade may be of a type that moves up and down to cut the recording medium D2 by the width of the recording medium D2. The point is that the recording medium D2 may be cut.

Next, the structure of the carriage CA will be described. A tape cassette TC (see FIGS. 2, 5, and 7) accommodating a narrow recording medium D1 and an ink ribbon IR, or the like, on the surface (mounting surface) side of the carriage CA.
Ink cassette RC containing only ink ribbon IR
(See FIG. 8) can be selectively placed, while a step motor SL (see FIGS. 3 and 6) is mounted on the back side thereof. The step motor SL is used to feed a tape such as an ink ribbon IR in a cassette TC set on a carriage CA, and is also used to press the recording head HD and a wide recording medium D2 at the time of the wide station WS. And used for separation.
The reason why the step motor SL is used as the drive source for the two purposes is to effectively use the driving force of the step motor SL.

A recording head HD is mounted below the carriage CA. On the recording surface side of the recording head HD, a large number of heating elements capable of generating heat in units of one dot are arranged in a line at a predetermined distance (printing distance). It is arranged for the width L1 (see FIG. 4). Then, a tape feeding mechanism using a driving force such as a step motor SL moves the recording medium (tape) D1 or the like in the cassette TC mounted on the carriage CA while intersecting in the direction in which the heating elements are arranged. Since the ink is conveyed to the recording surface side of the recording head HD, the heat generated by the heating element melts the ink of the ink ribbon IR, and the ink can be attached to the recording medium D1 in units of one dot.

As shown in FIG. 7, the tape cassette TC contains a narrow recording medium D1 and an ink ribbon IR used at the time of the tape station TS in a substantially rectangular cassette case. On the other hand, as shown in FIG. 8, the ribbon cassette RC contains a narrow ink ribbon IR used at the time of the wide station WS in a substantially rectangular cassette case.
Unlike the tape cassette TC, it does not contain a narrow recording medium D1.

Specifically, as shown in FIGS. 5 and 7, the tape cassette TC prints on a narrow recording medium D1 made of, for example, a transparent tape or the like, and prints on the narrow recording medium D1. And a double-sided adhesive tape YT, which is backed on a narrow recording medium D1 on which printing is performed, is wound around reels TC1, TC2, and TC3, respectively, and stored. An ink ribbon take-up reel TC4 for winding up the used ink ribbon IR is provided.

The narrow unused ink ribbon IR wound around the reel TC2 and pulled out from the reel TC2 is superimposed on the narrow recording medium D1, and is opened together with the narrow recording medium D1. The recording medium enters the section TC5 and passes between the recording head HD and the platen P1. Thereafter, the ink ribbon IR is separated from the recording medium D1 having a small width, and is driven by the step motor SL.
It reaches the take-up reel TC4 of R and is taken up by this reel TC4.

The tape cassette TC is moved to the carriage CA.
In a state where the reel TC4 is set above, a ribbon winding cam member PC4a projecting from the front side of the carriage CA is inserted into the reel TC4. The drive cam follower TC4b which is driven in a fixed manner is inserted. Therefore, reel TC4
Is rotated by receiving the driving force of the step motor SL via a gear train (described later) provided on the carriage CA under the engagement between the driving cam follower TC4b and the cam member PC4a. The IR can be wound up.

The double-sided pressure-sensitive adhesive tape YT is wound around a reel TC3 with the release paper facing out, with the release paper being superposed on one side, and stored. Then, the double-sided adhesive tape YT pulled out from the reel TC3 is
It passes between the tape drive roller TC6 and the tape laminating roller P3, and is adhered to the narrow recording medium D1 on the side where the release paper is not superimposed. It is desirable that the recording medium D2 also has a double-sided pressure-sensitive adhesive tape in which release paper is overlapped on one side, adhered to the back side of the medium D2.

Thus, the narrow recording medium D1 wound around the reel TC1 and pulled out from the reel TC1 is used as a pair of sensors S1 for detecting the end or for detecting the color.
E, the tape cassette T via the guide pin TB1 etc.
It passes through the opening TC5 of C. Thereafter, the narrow recording medium D1 to which the double-sided adhesive tape YT is attached is rotatably provided on one side lower portion of the tape cassette TC, and is driven by a step motor SL to rotate. The tape cassette TC passes through a gap between the tape laminating roller P3 disposed opposite to the roller TC6 and the tape cassette TC.
And is discharged from the main body frame 2. In this case, the double-sided adhesive tape YT is pressed against the recording medium D1 by the rollers TC6 and P3.

The tape laminating roller P3 is supported by a roller holder LD along with the platen P1. Therefore, the roller holder LD is provided with a tape drive roller TC.
6 and the tape bonding roller P3, and further, the recording head HD and the first platen P1 can be pressed and separated from each other. In this case, it is preferable that the first platen P1 be rotatable for transporting the recording medium D1, and therefore, it is desirable to use a cylindrical platen.

As shown in FIG. 7, the tape drive roller TC6 is provided with a through hole TC8, and the tape drive roller cam follower TC9 is formed in the through hole TC8. . Therefore, when the tape driving cam member PC6b projecting from the front surface side of the carriage CA is inserted into the through hole TC8 (see FIG. 9), the tape driving cam member PC6b engages with the cam follower TC9. it can. On the other hand, a tape feeding cam member PC3a projecting from the front side of the carriage CA is inserted into the reel TC3.
A drive cam follower that rotates integrally with the reel TC3 is not mounted inside C3, and the cam member PC3a only rotates idly.
Has no effect.

In the wide station WS, the ribbon cassette RC holds the recording surface D2 of the wide recording medium D2.
b (see FIG. 4), the both ends of the ink ribbon IR are wound on a reel RC for winding an unused ink ribbon.
1. The used ink ribbon is wound and stored on a reel RC2 for winding up the used ink ribbon. Then, the ink ribbon IR pulled out from the reel RC1 by the rotation of the reel RC2 according to a ribbon winding mode described later passes through the sensor SE, and then moves to the guide member R.
It passes through the opening RC3 of the ribbon cassette RC via B1 (see FIG. 8), and is further wound around the reel RC2 via the guide member RB2.

The ribbon cassette RC is mounted on the carriage CA.
In the state of being set on the upper side, the tape feeding cam member PC4a and the tape driving cam member PC6b projecting from the front side of the carriage CA are inserted into the reels RC4 and RC5, respectively. Unlike the case of TC, inside the reels RC4 and RC5,
The drive cam follower that rotates integrally with the reels RC4 and RC5 is not mounted. Therefore, since the cam member PC4a and the tape drive roller TC6 that receive the driving force of the step motor SL only rotate idly, the ink ribbon I
There is no effect on the feed of R, and it is not necessary to cut off the drive.

In the case of a color ink ribbon IR in the ribbon cassette RC, for example, a plurality of inks of cyan (C), magenta (M), yellow (Y) and the like are used.
In this order, a fixed length of each line, that is, one line L2 (FIG. 4)
(See (b)) in the length direction of the recording area. This is because while the recording head HD is transported in the main scanning direction of the recording medium D2, the recording head HD
This is because, in addition to recording one line L2 on the recording medium D2 via the ink ribbon IR for one line of one of cyan and yellow, one line L2 is also recorded in a color obtained by mixing these inks. . (Note that the cross line in FIG. 4B indicates a range in which the recording head HD performs main scanning and records one line L2). In this case, the recording medium D for one line of any one of magenta, cyan, and yellow is used.
After the recording on the recording medium D2, the recording head HD is superposed at the same position on the recording medium D2 via the ink ribbon IR for one line in another color and, if necessary, one line in another color. By recording, it is possible to record in a mixed color of cyan (C), magenta (M), and yellow (Y), for example, red, blue, and the like.

The difference between the tape cassette TC and the ribbon cassette RC is as shown in FIGS.
In addition to the presence or absence of the double-sided adhesive tape YT and the recording medium D1, reels TC2 and RC for winding an unused ink ribbon.
1 and the positions of the used ink ribbon take-up reels TC4 and RC2. That is,
Reel TC1 for recording medium D1 of tape cassette TC
Is the position of the reel RC1 of the ribbon cassette RC, and the position of the reel TC3 for the double-sided adhesive tape YT is the position of the reel RC2. This is because the tape cassette TC is a single color ribbon,
Ink ribbon IR for the length of recording medium D1 (tape)
However, the multi-color recording ribbon cassette RC on the wide station WS needs, for example, three colors of ink such as cyan, magenta, and yellow for a fixed length (that is, one line). This is because it is necessary to store the ribbon length three times or more the recording length. However, when the ribbon cassette RC is for a single color, cyan,
Three color inks such as magenta and yellow are not required.

Therefore, if the ribbon storage position is the same in both cassettes TC and RC, the cassette TC
The storage efficiency in the RC is deteriorated, and it is necessary to prepare an unnecessarily large cassette case.
This is not preferable from the viewpoint that the size increases. Therefore, the cassettes TC and RC used in the two recording stations TS and WS are configured as shown in FIGS. 7 and 8 so that their internal components do not interfere with each other and are arranged efficiently.

In order to distinguish between the tape cassette TC and the ribbon cassette RC, a plurality of (for example, seven) marking portions TC7 and RC6 are provided on the upper right side of the tape cassette TC and the ribbon cassette RC. Depending on whether these marking portions TC7 and RC6 are concave portions or not concave portions, for example, the distinction between the tape cassette TC and the ribbon cassette RC, and further, the width of the recording medium D1 in the tape cassette TC. , The ribbon cassette RC indicates the type of monochrome or color. Then, as shown in FIG.
7, the detection sensor SQ arranged on RC6 is
7. By detecting the presence or absence of the concave portion of RC6, the control device CP determines the difference between the cassettes TC and RC,
It is possible to identify a width of 1, a single color or a color, and the like.

Since the sensor SE is set in the ribbon cassette RC so as to detect the yellow ink of the ink ribbon IR, when the yellow ink is conveyed to the sensor SE, the control device CP It can be determined that the ink is yellow ink. This is because, in the case of color printing, the leading end of the yellow ink is detected, and the control device CP controls the conveyance of each of the cyan, magenta, and yellow ribbons having a fixed length L2, and the printing head HD This is to prevent recording in a different color. On the other hand, when the ink ribbon IR is a single color, for example, one color ink such as black is applied to the entire surface of the base material, but since a detection mark (not shown) is provided at the end, the sensor SE is used. Detects a mark for detection and outputs a detection signal to the control device CP, so that the control device CP
Can determine the end of the ink ribbon IR.

Next, a mechanism for winding the ink ribbon IR in the ink cassette RC used in the wide station WS will be described with reference to FIGS. FIG.
0 to 13 are the side surfaces of FIG. 9, that is, arrows II, II-II, and II.
Although the drawings are viewed from I-III and IV-IV, the positions between the components are shown as shifted or omitted in order to make it easier to understand the positional relationship between the components. Therefore, the components shown in FIG. 9 do not always match the components shown in each of FIGS. For example, the pinion P in FIG.
N is located at a regular position, whereas in FIG.
13, the pinion PN and the swing lever YB are connected to the gear C11.
The positions are shifted to make it easier to see. Further, the sensor SZ, the cam follower CF and the like are not shown in FIG. 13 in order to make the gear C11 and the like easy to see. On the upper side of the carriage CA, as shown in FIG.
N is provided, and this pinion PN can mesh with a rack LA (see FIG. 5) extending in the left-right direction of FIG. 2 over the length of the timing belt TB. for that reason,
The pinion PN, which is rotated by the rack LA in accordance with the movement of the carriage CA, applies its rotational force to a gear train R1, R2 for winding on the carriage CA described below.
To rotate the reel RC2 in the ink cassette RC to wind up the used ink ribbon IR.

That is, the pinion PN is connected to the large-diameter gear portion P.
Na and a small-diameter gear portion PNb are provided in upper and lower two stages (FIG. 12,
13), and the small-diameter gear portion PNb meshes with the rack LA. On the other hand, the large-diameter gear portion P of the pinion PN
Na consists of a large-diameter gear R1b and a small-diameter gear R
1a, small-diameter gear portion R1 of first winding gear R1
meshes with a. The cam member PC3a inserted into the reels TC3 and RC2 has its rotation axis P as shown by a virtual line in FIG. 13 (not explicitly shown in FIGS. 9 to 12).
It is stored so as to cover C3b. This rotation axis PC3b
Is mounted with a swing bar BD that swings around the axis PC3b.

Since the second take-up gear R2 is rotatably attached to the tip of the swing bar BD, the second take-up gear R2 is configured to swing the swing bar BD. As a result, the large-diameter gear portion R of the first winding gear R1
1b may or may not mesh. This is the carriage CA in the wide station WS.
This is because the reel RC2 needs to wind up the ink ribbon IR at the time of recording in the forward movement (movement to the right in FIG. 2). Thus, the large-diameter gear portion R1b and the take-up gear R2 mesh with each other so as to obtain the driving force due to the rotation of the pinion PN and rotate the cam member PC3a. On the other hand, at the time of non-recording when the carriage CA moves backward (moves to the left in FIG. 2), it is necessary to prevent the driving force due to the rotation of the pinion PN from being obtained in order to prevent the winding of the ink ribbon IR. The large-diameter gear portion R
1b and the winding gear R2 do not mesh with each other.

When the large-diameter gear portion R1b meshes with the winding gear R2, the gear R2 is rotatably supported by the rotating shaft PC3b.
(Described only in FIG. 13), and the winding gear R3
Can be rotated. Then, a spring member BZ (shown by a phantom line in FIG. 13) mounted on the winding gear R3 generates a torque for winding the ribbon by the rotation of the gear R3, and rotates the cam member PC3a. Let
The ink ribbon IR can be wound up.

Next, a mechanism for feeding the ink ribbon IR and the like in the tape cassette TC mounted at the time of the tape station TS will be described. On the back side of the carriage CA,
As described above, the step motor SL as a drive source (drive motor) is fixed. As clearly shown in FIGS. 9, 10 and 11, the drive shaft SL1 of the step motor SL projects through the through-hole of the carriage CA toward the front surface side of the carriage CA. Gear G1 is attached. Gears C2, C3 and the like described below are rotatably mounted on the front surface side of the carriage CA to form a ribbon feed gear train. C2, C4, PC4c and C1, C
2, C4, C5, and PC6a in this order,
The drive cam follower PC4a is rotated for R winding, and the tape drive cam member PC6b is rotated.

Specifically, as shown in FIGS. 9 and 11, on the front surface side of the carriage CA, a first carriage carriage in which a small-diameter gear portion C1a and a large-diameter gear portion C1b are formed in upper and lower stages. Gear C1 is rotatably mounted,
The large-diameter gear portion C1b meshes with a gear G1 that rotates integrally with the drive shaft SL1. In addition, the large-diameter gear portion C1b
A second gear C2 for the carriage and a third gear C3 for the carriage are rotatably mounted on the left and right sides of the small-diameter gear portion C1a located above the second gear C1a.

The carriage second gear C2 is used when transmitting a driving force for feeding the tape of the tape cassette TC, and the driving force is transmitted to a carriage gear C4 connected to the gear C2. Is done. That is, the second gear C2 for the carriage, as clearly shown in FIGS.
The large-diameter gear portion C2a and the small-diameter gear portion C2b are formed as upper and lower stages, and the large-diameter gear portion C2a meshes with the small-diameter gear portion C1a of the first gear C1. A small-diameter gear portion C located below the large-diameter gear portion C2a of the gear C2.
2b meshes with the fourth carriage gear C4 rotatably attached to the front side of the carriage CA.

As shown in FIGS. 9 and 10, a tape which can be inserted into the reel TC4 for winding the used ink ribbon IR in the tape cassette TC is provided on the side of the carriage fourth gear C4. Cam member PC for feeding
4a, a gear PC4c provided below the cam member PC4a meshes with a fourth gear C4 for the carriage. The fourth carriage gear C4 meshes with a fifth carriage gear C5 disposed on the left side thereof, and an idle gear IG is provided on the recording head HD side of the fifth carriage gear C5. Are engaged. Also,
The recording medium D is provided beside the fifth carriage gear C5.
1 and a double-sided adhesive tape YT are provided with a cam member PC6b which can be inserted into a tape drive roller TC6 for pressing and bonding the tapes to each other.
The gear PC6a provided at the lower part of the gear 6 meshes with the fifth carriage gear C5.

When the drive shaft SL1 of the step motor SL rotates clockwise (or counterclockwise) as shown in FIG. 9, the first gear C1 for the carriage is rotated.
Rotates counterclockwise (clockwise), and similarly, the second gear C2 for the carriage rotates clockwise (counterclockwise).
Meanwhile, the fourth gear C4 for the carriage rotates counterclockwise (clockwise) and the fifth gear C5 for the carriage rotates clockwise (counterclockwise), whereby the gear PC6 is rotated.
a rotates clockwise (counterclockwise) to rotate the tape driving cam member PC6b counterclockwise (clockwise) and also rotates the gear PC4c counterclockwise (clockwise). Then, with the rotation of the gear PC4c in the counterclockwise direction, a torque for winding the tape cassette TC is generated by the tightening action of the spring OSN mounted below the cam member PC4a.
The take-up reel TC4 is used for the used ink ribbon IR.
Take up. On the other hand, when the gear PC4c rotates clockwise, the take-up reel TC4 does not send out the ink ribbon IR because the spring OSN is loosened.

The idle gear IG is a gear rotatably mounted on the platen P1 when the roller holder LD is close to the tape cassette TC and the platen P1 is in contact with the recording head HD. (Not shown) to rotate the platen P1.

On the other hand, the rotation of the carriage third gear C3 is performed by the recording head HD in the wide station WS.
And a driving force for pressing and separating the platen P1. Is transmitted. That is, as shown in FIGS. 9, 10, and 12, the third gear C3 for the carriage has a large-diameter gear portion C3a and a small-diameter gear portion C3b formed as two upper and lower stages. The large diameter gear portion C3a meshes with the small diameter gear portion C1a of the first gear C1. Further, the small-diameter gear portion C3b of the third gear C3
Meshes with the sixth carriage gear C6 rotatably attached to the front side of the carriage CA.

On the left side of the sixth carriage gear C6, as shown in FIGS.
A swing lever YB that protrudes in an arc shape toward the outside of A is provided, and the swing lever YB can rotate around a rotation axis YB1 that penetrates the base thereof. A seventh carriage gear C7 is rotatably mounted between the swinging lever YB penetrating the rotation shaft YB1 and the carriage CA, and the seventh carriage gear C7 is a sixth carriage gear. Gear C6, and meshes with an eighth gear C8 rotatably attached to the tip end of the swing lever YB base.

As shown in FIGS. 9 and 12, a pair of ninth gears C9 for the carriage are rotatably mounted on the left and right sides of the eighth gear C8 for the carriage, as shown in FIGS. When the swing lever YB swings right and left around the rotation axis YB1, the eighth gear C8 for the carriage is used.
Can be present at a position meshing with any one of the pair of ninth gears C9 for carriage, and at a position not meshing with any of the ninth gears C9 for carriage. ing.

Here, the fact that the eighth gear C8 exists at a position where it does not mesh with any of the ninth gears C9 means that:
This means that the eighth gear C8 is located at a middle position between the pair of ninth gears C9 for the carriage. This position is set when the tip end portion YB2 of the swing lever YB is located at the upper step portion GIa on the left side of FIG. 2 of the guide member GI above the rack LA (see FIG. 9). In other words, the upper step GIa serves as a holding unit. In this case, the driving force of the step motor SL is transmitted to the following carriage gears C3, C6, C7, C8.
It is not transmitted to the gear C9 and thereafter. As a result, in the tape station TS, the recording head HD and the platen P1 are not pressed and separated from each other.

On the other hand, the eighth gear C8 for the carriage
Is meshed with either one of the pair of carriage ninth gears C9.
However, when the carriage CA moves down the upper step GIa of the guide member GI to the right (wide station WS) in FIG. 2 and the step motor SL rotates clockwise, the transmission of each gear described above is performed. The swing lever YB is tilted slightly to the right, and the eighth gear C8 is moved to the right of the ninth gear C8.
When the gear C9 meshes with the gear C9, or when the step motor SL rotates counterclockwise, the transmission of the gears causes the rocking lever YB to fall slightly to the left, thereby causing the eighth gear C8 to rotate. This means that the gear meshes with the ninth gear C9 on the left side. In this case, the driving force of the step motor SL is transmitted after the carriage gear C9.

Incidentally, the eighth gear C8 is a step motor S
By meshing with one of the two left and right gears C9 according to the rotation direction of L, the driving force of the motor SL is transmitted to the gear C9, and the bidirectional driving of the motor SL can be used. When two operations are performed by one motor as described above, each operation generally uses only one direction rotation of the motor in many cases, and the gear C8 supported by the swing lever YB is one of the swing levers YB. Depending on the direction of rotation, the gear should be engaged with another gear C9 or switched between non-engagement. However, in the case where the bidirectional driving of the motor SL is used as in the present embodiment, simply using the swing lever YB requires one.
During rotation in the direction, the swing gear (that is, the eighth gear C8) escapes from the other gear C9 and cannot be driven. Therefore, gears for engagement (that is, a ninth gear C9) are provided at two positions on both sides of the swing lever YB, respectively, to prevent the eighth gear C8 from escaping from the ninth gear C9. I have. As a result, when the swing lever YB and the eighth gear C8 swing right and left, they can always mesh with any one of the two gears C9. The swing lever YB
When the eighth gear C8 does not swing right and left, the eighth gear C8 may be in a neutral state in which the eighth gear C8 does not mesh with any of the gears C9 depending on the position where the ninth gear C9 is provided.

The pair of ninth gears C9 mesh with the tenth gear C10 for the carriage. The tenth carriage gear C10 is located above the swing lever YB, is rotatably attached to the rotation shaft YB1, and meshes with the eleventh carriage gear C11. Therefore, the eleventh gear C11 for the carriage is
The head drive cam gear CK meshes with the head drive cam gear CK, and the head drive cam gear CK can rotate around the rotation axis PC3b.

As a result, when the drive shaft SL1 of the step motor SL rotates clockwise (or counterclockwise) as shown in FIG. 9, the first gear C1 for the carriage is rotated.
It rotates counterclockwise (clockwise), and similarly, the third gear C3 for the carriage rotates clockwise (counterclockwise).
The sixth gear C6 for the carriage is counterclockwise (clockwise), the seventh gear C7 for the carriage is clockwise (counterclockwise), and the eighth gear C8 for the carriage is counterclockwise (clockwise). Around) the ninth gear C9 for the carriage,
The tenth carriage C10 rotates clockwise (counterclockwise), the eleventh carriage C11 rotates counterclockwise (clockwise), and the tenth gear C11 rotates clockwise (counterclockwise). The head drive cam gear CK can be rotated counterclockwise (clockwise).

On the lower surface side of the head driving cam gear CK, that is, on the carriage CA side, a head driving cam CKa for pressing and separating the recording head HD and the platen P1.
Are provided integrally, and the head driving cam CKa
Has a large diameter portion CK1 and a small diameter portion CK2, as shown in FIG.

On the outer peripheral side of the head driving cam CKa,
The cam follower CF is supported by the swing lever YP so as to contact the outer peripheral surface thereof.
When the recording head HD comes into contact with the large diameter portion CK1 of the head driving cam CKa, the recording head HD comes into pressure contact with the platen P1, whereas when it comes into contact with the outer periphery of the small diameter portion CK2, it is separated from the platen P1. . That is, the head H
D is, as shown in FIGS.
It is rotatable around one direction, and can be pressed against and separated from the platen P1.

On the back side of the carriage CA, FIG.
As shown in FIGS.
And one end H of the press-contact and release member HB is provided.
B1 is connected to the base side of the head HD. Also,
The springs AS and RS serving for release and pressure contact are connected to the other end portion HB2 of the press-contact and release member HB, respectively. Another spring RS is connected to the right side of the carriage CA in FIGS.

When the cam follower CF comes into contact with the large-diameter portion CK1 of the head drive cam CKa, as shown in FIG.
As shown in FIG. 5, the spring AS attached to the back side of the carriage CA is greatly elongated,
The member HB overcomes the pulling force of the spring RS.
Is pulled to the head drive cam gear CK side. Then, one end HB of the pressure contact and release member HB
1 moves upward, the head HD
It rotates clockwise one turn and makes pressure contact with the platen P1.
On the other hand, as shown in FIG.
When F approaches the small-diameter portion CK2 of the head drive cam CKa, the spring AS is not extended, and the tension of the spring AS balances the tension of the spring RS.

As a result, the other end HB2 of the pressure contact and release member HB moves away from the head drive cam gear CK, and the one end HB1 of the pressure contact and release member HB moves downward. And separates from the platen P1. As a result, the press-contact and release member HB is connected to the platen P1 and the recording head H.
A pressure contact / separation means for bringing the pressure contact state with D and the separation state is constituted. FIGS. 15 and 16 show a state before many gears are mounted on the front side of the carriage CA. The driving cam gear CK and the eleventh gear C1
1. The relationship between the springs RS, AS, and the like is clearly indicated.

As described above, the drive cam gear CK receives the drive of the step motor SL as the drive motor and also functions as a drive transmission member for transmitting the drive to the cam follower CF as another member. And
As shown in FIG. 17, the gear CK has a tooth portion CKg meshing with the eleventh gear C11 on its outer periphery, and also covers about two-thirds of the entire tooth portion CKg. A collar CKb is provided. A transmission type sensor SZ for detecting the presence or absence of the flange CKb is provided above the left side of the carriage CA in FIG. 9, and the sensor SZ detects the presence or absence of the flange CKb. By doing so, the recording head HD and the platen P1 play a role of detecting the origin at the time of pressing and separating. still,
FIG. 17 is a diagram of the head drive cam gear CK viewed from the back side with respect to FIGS.

More specifically, the head drive cam gear CK shown in FIG. 16 rotates counterclockwise to reach FIG. 15, that is, the cam follower CF has a small diameter portion CK2 and a large diameter portion CK1 of the head drive cam CKa. During the transition operation for transitioning between the positions, the flange portion CKb of the head drive cam gear CK is located at the detection position of the transmission sensor SZ, and is shielded by the flange portion CKb. When the recording head HD is located at a position where the recording head HD is pressed against the platen P1 (the cam follower CF is at the end of the large-diameter portion CK1) or separated from the platen P1 (the cam follower CF is at the small-diameter portion CK2), the flange portion CKb transmits light. It is no longer present at the detection position of the type sensor SZ and enters the transmission state. The position where the flange CKb is located does not always match the position of the large-diameter portion CK1 and the small-diameter portion CK2 of the head drive cam CKa. This is because the position of the sensor SZ for detecting the flange CKb is shifted. Because there is.

In such a case, when detecting the origin position for pressing and releasing the recording head HD, the sensor SZ
If only the absence (transmission) or presence (shielding) of Kb is detected, it is not possible to determine the position of the head drive cam gear CK in the pressed state, the separated state, and the transition state. That is, the control device CP determines that the collar portion CKb is
In a transmission state that is not present at the detection position of the transmission sensor SZ, whether the head HD is in pressure contact with the platen P1 or is separated from the platen P1, and furthermore, the flange portion CKb is located at the detection position of the transmission sensor SZ. If it exists, it cannot be determined whether the transition from the pressed state to the separated state or the transition from the separated state to the pressed state.

Therefore, where the flange CKb of the outer peripheral tooth CKg of the head drive cam gear CK exists, the tooth C
A portion having no Kg, that is, a missing tooth CKc is provided. In the missing tooth CKc, the eleventh gear C11 does not mesh with the outer peripheral tooth portion CKg. That is, the head drive cam gear CK as the drive transmission member is connected to the step motor S
L is provided with a missing tooth CKc as a non-transmission area that does not transmit the driving of the gear L to another member.
Before 1 is reached, the head drive cam gear CK rotates. Then, the head drive cam gear CK shown in FIG.
However, when the eleventh gear C11 approaches the missing tooth CKc when rotated clockwise (counterclockwise in FIGS. 15 and 16), the head driving cam gear CK stops rotating any further due to the missing tooth CKc. Therefore, the control device CP
Even if more pulses than necessary are applied to the step motor SL, the head drive cam gear CK cannot be rotated, and the flange portion CKb is present at the detection position of the transmission sensor SZ and does not enter the transmission state. .

On the other hand, when the head drive cam gear CK shown in FIG. 17 rotates counterclockwise (FIGS.
6, the clockwise rotation), before reaching the missing tooth CKc, from the shielding state in which the flange CKb is at the detection position of the transmission sensor SZ, the transmission in which the flange CKb is not at the detection position of the transmission sensor SZ. State, the control device CP
Can determine the rotation direction of the head drive cam gear CK.
Then, when the control device CP applies a pulse of a predetermined amount or more to the step motor SL to rotate the head driving cam gear CK in a direction to separate the head HD, the missing tooth CKc of the head driving cam gear CK acts. The position is the origin for press-contact / release control of the recording head HD. As a result, when the control device CP knows the rotation direction of the head drive cam gear CK and the origin for the press-contact / release control, the control device CP applies a pulse from the origin to the stepping motor SL to be separated, Alternatively, it is possible to determine whether the state is a pressed state, or a state of transition from the pressed state to the separated state, or a state of transition from the separated state to the pressed state.

Therefore, the tape printer 1 of the present embodiment
Is driven, it is necessary to detect the origin for press-contact and release of the recording head HD.
However, it suffices to apply a predetermined amount or more of pulses to the step motor SL to determine whether or not the transmission sensor SZ changes from the signal in the shielding state to the signal in the transmission state. That is, when the change from the signal in the shielded state to the signal in the transparent state is not detected, the control device CP drives the step motor SL in the opposite direction to change from the signal in the shielded state to the signal in the transparent state. After confirmation, the rotation direction of the cam gear CK is determined.

According to the above-described embodiment, the control means CP as the discriminating means discriminates the pressed state and the separated state between the platen P2 and the recording head HD, and changes the pressed state from the separated state or from the separated state to the pressed state. The transition state can be determined. Specifically, the detection sensor SZ as a detection unit determines the pressed state and the separated state and the transition state, and based on the result of the detection sensor SZ, The pressure contact state and the separated state can be determined.

Further, the missing tooth CK of the head drive cam gear CK
c is provided with a notch hole CKd.
An elastic piece CKE constituting a part of the tooth part CKg is formed at d, and the elastic piece CKE has an elastic force. Therefore, when the eleventh gear C11 approaches the head driving cam gear CK and the head driving cam gear CK rotates clockwise, the elastic piece CKe is urged toward the eleventh gear C11 by the elastic force. Nevertheless,
The elastic piece CKe is repelled in the center direction of the head drive cam gear CK (represented by a virtual line in FIG.
17, the head drive cam gear CK cannot be rotated clockwise in FIG.

On the other hand, when the head drive cam gear CK rotates counterclockwise in FIG. 17, the eleventh gear C11
Can engage with the elastic piece CKE and the teeth CKg on the outer periphery of the head drive cam gear CK, so that the head drive cam gear CK can be rotated. However, when the eleventh gear C11 approaches the head drive cam gear CK,
After continuing to rotate the head drive cam gear CK in the clockwise direction in FIG. 17, even if the head drive cam gear CK is to be rotated in the counterclockwise direction, the teeth of the eleventh gear C11 and the teeth CKg on the outer periphery of the head drive cam gear CK. Does not mesh with
Therefore, a leaf spring UB shown by a broken line in FIGS. 15 and 16 is attached to the carriage CA so that the teeth of the eleventh gear C11 can mesh with the teeth CKg on the outer periphery of the head drive cam gear CK. The leaf spring UB urges the head drive cam gear CK in the clockwise direction in FIGS.

A sensor S for detecting the presence of the recording head HD is provided on the rack LA on the back side of the swing lever YB in FIG. 9, that is, in the area where the line recording mode is performed.
Y is provided, and the sensor SY plays a role as a detection unit for detecting an initial operation of the recording apparatus. The sensor SY is connected to the recording head H
D is mounted on the wide station W
When transported between S and the tape station TS,
When the projection RZ provided on the carriage CA comes into contact with the operation piece SY1, the carriage CA is detected, and the control device CP can determine the position of the carriage CA.

Next, a mechanism for pressing or separating the recording head HD and the like of this embodiment from each other and the platen P1 and the like for transporting and supporting the recording medium D1 will be described. The mechanism for pressing or separating is shown in FIG.
As shown in FIG. 3, a drive motor SN capable of driving the drive shaft SN1 to rotate forward and reverse, and a drive shaft S of the drive motor SN
And rotation transmitting means SD for receiving the rotation of N1. The rotation transmission means SD receives the rotation of the drive shaft SN1 in one direction, and as shown in FIG. 21, moves the roller holder LD supporting the platen P1 and the tape bonding roller P3 to the recording head HD and the recording head HD. Tape drive roller TC6
The roller holder LD that supports the platen P1 and the tape laminating roller P3 by receiving the rotation in the opposite direction of the drive shaft SN1 while performing the pressing operation of pressing against
Can be separated from the recording head HD and the tape drive roller TC6.

Specifically, the step motor SN is fixed to the pair of tape stations TS, and the step motor SN is connected to the recording head HD and the platen P1 at the tape station TS as described above. Pressing and separating between and wide station WS
It is used to selectively perform paper feeding at the time. Thus, the stepping motor SN as a driving source is
The reason for utilizing the two uses is to effectively utilize the driving force of the step motor SN.

Between the short-side chassis HS1 and the long-side chassis HS2, there are provided a gear train GY for sheet feeding, pressure contact and separation, which constitutes a part of the rotation transmitting means SD, and the like. These gear trains GY and the like are shown in FIG.
As shown in FIGS. 19 and 20, the rotation of the drive shaft SN1 of the step motor SN receives the transmission of the driving force for press-contact and separation between the recording head HD or the like and the platen P1 or the like during the tape station TS. Wide station WS
The transmission of the driving force for feeding the paper at the time is configured to be selectively switched. Specifically, the drive shaft SN1 of the step motor SN is connected to the short side chassis H
Through the notch (not shown) of S1, the long side chassis H
A gear G2 that protrudes toward S2 and that rotates integrally with the drive shaft SN1 is attached to the distal end side of the drive shaft SN1.

Therefore, the gear G meshing with the gear G2
3, a large-diameter gear portion G3a is used to transmit a driving force for press-contact and separation between the recording head HD or the like and the platen P1 or the like.
The gear G3 comprises a small-diameter gear portion G3b, a slidable slide gear SG, a first bevel gear K1, a second bevel gear K2, a double-geared gear NG as a transmission delay unit, a sector gear ED, and the like. The rotation of the drive shaft SN1 can be transmitted via the rotation transmission means SD (see FIGS. 6, 20, and 21). As a result, the forward or reverse rotation of the drive shaft SN1 reciprocates the roller release rod LT left and right (see FIGS. 21A, 21B, and 21C), and the platen P1 and the tape supported by the roller holder LD. The laminating roller P3 can be pressed against and separated from the recording head HD and the tape drive roller TC6, respectively.

Further, the structure for pressing and separating the platen P1 and the like from the recording head HD and the like will be described in detail with reference to FIG. 21. It is movably supported, and is rotatably supported on its base end side by a rotation axis LD1 so as to be close to and away from the carriage CA. On the lower surface side of the roller holder LD, a cam portion LT1 provided with a rotating roller at the tip of the roller release rod LT abuts, and the roller release rod LT moves leftward (FIG. 21 ( b)
), The cam portion LT1 pushes up the roller holder LD, and the platen P1 and the tape laminating roller P3 are
Further, the recording head HD and the tape drive roller TC6 can be pressed against each other (see FIG. 21C).
On the other hand, when the roller release rod LT moves to the right, the cam portion LT1 is moved to the roller holder LD.
The roller holder LD is lowered by its own weight without pushing up the lower surface of the roller holder LD.
(See FIG. 21A).

The roller release rod LT has a distal end portion LB1 of a swing lever LB connected to a base end side thereof.
By swinging right and left in FIG. 21, it is configured to move in the left and right direction. That is, the swing lever L
The swing of the distal end portion LB1 of the swing lever B is based on the base end portion L of the swing lever LB.
B2 is driven by a drive shaft S via a first bevel gear K1, a second bevel gear K2, and a double gear NG.
This is performed by rotating integrally with the sector gear ED that receives the transmission of the forward or reverse driving force of N1. Specifically, the second bevel gear K2 rotates counterclockwise (or clockwise), the two-layered gear NG rotates clockwise (counterclockwise), and the sector gear ED rotates counterclockwise. By turning (clockwise), the tip LB1 of the swing lever LB moves rightward (leftward) in FIG. 21, and further, the roller release rod LT moves rightward (leftward) in FIG. Go to However, the mode of the rotation transmitting means SD is not necessarily limited to the above-described embodiment. For example, a mode different from the above-described gear train or the like may be adopted.

The rotation transmitting means SD rotates the drive shaft SN1 in one direction (forward rotation) to perform the pressing operation, and then rotates the drive shaft SN1 in the opposite direction (reverse rotation). Accordingly, when the separating operation is performed, a double gear NG is provided as a transmission delay unit that delays the transmission of the drive shaft SN1 for a predetermined time without immediately transmitting the rotation of the drive shaft SN1 in the opposite direction.

As shown in FIG. 22, this transmission delay portion superimposes two gears NG so that their rotation axes NG3 coincide with each other, and a sliding space is provided on the side surface of one gear NG1. As well as a protrusion NGb fitted on the side surface of the other gear NG2. Therefore, when the protrusion NGb slides between both ends NGa1 and NGa2 inside the elongated hole NGa, the drive shaft SN1 of the step motor SN as the drive motor rotates in the opposite direction. However, the rotation is not transmitted immediately.

More specifically, the gear NG2 is located on the near side of the paper of FIG. 21 and the gear NG1 is overlapped with the gear NG1 on the other side of the paper of FIG. The rotation shaft NG3 passes through the through-hole, so that the gears NG1 and NG2 can rotate around the rotation shaft NG3 as the rotation center. And the gear NG1
As shown in FIG. 6, the gear meshes only with the sector gear ED, whereas the gear NG2 meshes only with the base gear K2a of the second bevel gear K2.

For this reason, the gear NG2 is rotated by the second bevel gear K2, and the protrusion NGb fitted inside the elongated hole NGa is formed at both ends NG of the elongated hole NGa.
a1 and NGa2, the gear NG2 does not rotate the gear NG1 even if the drive shaft SN1 of the step motor SN rotates in the opposite direction. Do not immediately transmit to the sector gear ED. Then, the protrusion NGb is formed at both ends N of the elongated hole NGa.
Any one of the ends NGal, Ga1, NGa2,
Immediately after contact with NG2, the gear NG2 becomes the gear NG1.
Is started to rotate, and the rotation of the drive shaft SN1 is transmitted to the sector gear ED.

As a result, a predetermined time during which the transmission delay section is operating, that is, a time during which the protrusion NGb is sliding between both ends NGa1 and NGa2 of the elongated hole NGa, during the time when the drive shaft SN1 is driven. Is not immediately transmitted, and the transmission of the drive by the rotation transmitting means SD is released. for that reason,
The load or the like applied between the detent torque of the step motor SN or the gears K1, K2, NG, ED, etc. is eliminated or reduced. However, the mode of the transmission delay unit is not necessarily limited to the above-described embodiment, and a mode different from the above-described mode may be adopted.
In addition, a “so-called play” and a “dead zone in which the drive by the drive shaft is not immediately transmitted” corresponding to the transmission delay unit may be provided mechanically or electrically, or other configurations may be employed.

When the cam portion LT1 of the roller release rod LT moves leftward in FIG. 2 and FIG.
In this state, the platen P1 is sandwiched between the roller holder LD and the bottom surface 2b of the main body frame 2.
And the tape laminating roller P3 serves as a holding means for keeping the recording head HD and the tape driving roller TC6 pressed against each other, so that the platen P1 etc. can be used without continuing to rotate the step motor SN. The recording head HD can keep pressure contact with the recording head HD and the like, and the recording head HD can record on the recording medium D1 supported between the platen P1 and the recording head HD. Therefore, in FIG. 21C, the drive shaft SN1 is rotated in the opposite direction so that the protrusion NGb moves from one end of the elongated hole NGa on the recording head HD side to the other end on the step motor SN side. It is desirable to control the operation of the step motor SN.

An operation unit (not shown) for releasing the state where the platen P1 and the like and the recording head HD are pressed against each other and separating the platen P1 and the like and the recording head HD from each other.
Is provided at a position where it can be operated from the outside on the back side of the main body frame 2. However, the operating section is not necessarily limited to this mode. As shown in FIG. 23, for example, the operating section may be attached to the base end side of the rod LT as an operating lever LX. Accordingly, if the tip of the operating lever LX is pinched and rotated in a state where the protrusion NGb has moved to the other end of the elongated hole NGa, the transmission of the drive by the rotation transmitting means SD is released. Therefore, the detent torque of the step motor SN or the gear K1,
There is no load between K2, KG, etc.
Alternatively, the platen P1 and the like and the recording head HD and the like can be easily separated from each other with a small force because of the small size.

Next, the manner in which the paper feed rollers JR1, JR2 and the like are rotated will be described. Slide gear SG
Are the springs SB1 and SB2 and the switching lever KB
Slides in the left and right directions in FIGS.
The gear can selectively mesh with the small-diameter gear portion G3b. The large-diameter gear portion G3a of the gear G3 is connected to the wide station WS.
In order to transmit the driving force for feeding the paper at the time, the small-diameter gear portion G3b of the gear G3, the slide gear SG, and the first paper feeding side arranged along the long-side chassis HS2.
The rotation of the step motor SN is transmitted through the gears Y1 to Y7 of the sheet feed roller unit JR1, JR
Rotate 2 etc. Thus, the slide gear SG is connected to
9 and 20 to be used as a driving force for feeding the paper in the wide station WS, or the recording head HD in the tape station TS.
And the platen P1 etc.
The driving force of the step motor SN as a driving source is effectively used.

More specifically, the long side chassis HS
Two gears, that is, the gear G3 and the second gear Y2 for feeding the paper, are rotatably arranged side by side in the axial direction on a rotation shaft HS3 protruding from the second side toward the short side chassis HS1. The gear G3 attached to the short-side chassis HS1 has a large-diameter gear portion G3a and a small-diameter gear portion G3b formed integrally therewith, whereas the gear G3 adjacent to the long-side chassis HS2 has a large-diameter gear portion G3a and a small-diameter gear portion G3b. 2 gear Y2
Has a flat plate shape. A slide gear SG for switching the driving force is provided on the side of the gear G3. The slide gear SG is short from the long side chassis HS2 in a state in which the slide gear SG is meshed with the small diameter gear portion G3b of the gear G3. Support shaft HS protruding toward the side chassis HS1
4 can be slid.

The support shaft HS4 has a long side chassis H
From S2 toward the short side chassis HS1, a pressing spring SB1, a slide gear SG, and a sliding member F1 are attached in that order, and the pressing spring SB1
Urges the slide gear SG and the slide member F1 from the long side chassis HS2 toward the short side chassis HS1. A support shaft HS5 extends from the wide station WS toward the tape station TS on the rear side of the long side chassis HS2, and a stopper HS6 on the distal end of the support shaft HS5 is a slide member. By attaching F1 and the pressing spring SB2 to the support shaft HS5, the pressing spring SB2 urges the slide member F1 toward the wide station WS.

Then, a plurality of pressing springs SB1, S
By the action of B2 and the switching lever KB described below, the slide member F1 moves the slide gear SG so as to approach the long side chassis HS2 side or the short side chassis HS1 side, and the first bevel gear The gear is meshed with either the attached gear K1 or the first gear Y1.

The switching lever KB is a component for meshing the slide gear SG with one of the first bevel gear K1 and the first gear Y1, as shown in FIG. A switching lever KB having first, second, and third arm portions KB1, KB2, and KB3 from the left side is rotatably attached around an axis KB4 attached to the long-side chassis HS2. I have. The switching lever KB abuts on the slide member F1, and moves the slide gear SG together with the slide member F1 to the long side chassis HS2 (ie, the wide station WS).
Side or the short side chassis HS1 (that is, the tape station TS).

That is, when the carriage CA is located at the tape station TS, as shown by the solid line in FIG. 24, the first and second arms KB1 and KB2 move toward the tape station TS around the axis KB4. The third arm portion KB3 is in a state of standing up in a state of falling toward the
Of the arm KB1 presses the slide member F1,
It has been moved to the tape station TS side (see FIG. 20). On the other hand, when the carriage CA is located at the wide station WS, the first and second arms KB1 and KB2 are in the raised state and the third arm is as shown by the phantom line in FIG. In the state in which KB3 is tilted toward the wide station WS, the tip of the first arm KB1 does not press the slide member F1 as described above, and the slide member F1 is moved by the spring spring SB2 to the long side chassis. HS2 (Wide Station W
S), and comes into contact with the first arm KB1 (see FIG. 19).

When the carriage CA moves from the tape station TS to the wide station WS (moves from the solid line to the imaginary line in FIG. 24), the projection CP1 as a switching operation portion of the carriage CA is moved to the third arm portion KB3 side. Section, the switching lever KB is moved to the wide station W.
When pushed down to the S side, it is rotated by about 90 degrees about the axis KB4, and the engagement between the tip of the first arm KB1 and the slide member F1 is released. On the other hand, the carriage CA moves from the wide station WS to the tape station TS (FIG. 2).
4 from the virtual line to the solid line)
The projection CP1 of A comes into contact with the side of the second arm KB2, and the switching lever KB is pushed down to the tape station TS side, and is rotated substantially 90 degrees around the axis KB4, so that the first arm KB1 is rotated. Is engaged with the slide member F1.

As a result, the switching lever KB and the first
Of the slide member F1 under the action of the pressing spring SB1
Is moved toward the short side chassis HS1 (tape station TS) (see FIG. 20), whereby the slide gear SG meshes with the small-diameter gear portion G3b of the gear G3. As a result, the slide gear SG becomes the first bevel gear K1.
As described above, the driving force for pressing and separating the recording head HD and the roller holder at the time of the tape station TS is transmitted as described above.

On the other hand, when the slide member F1 moves toward the long side chassis HS2 (wide station WS) under the action of the switching lever KB and the second pressing spring SB2 (see FIG. 19), the slide gear SG is moved.
Is a first gear Y1 arranged on the side of the second gear Y2.
Mesh with. As a result, the driving force for feeding the paper at the time of the wide station WS is changed to the second speed as the gear train.
To the seventh gear Y7 and the like.

Specifically, the first gear Y1 has a large diameter portion Y1a meshing with the slide gear SG and the large diameter portion Y1a.
, A small-diameter portion Y1b on the long-side chassis HS2 side, and the small-diameter portion Y1b is attached to the end of the shaft JR2b of the paper feed roller JR2 and meshes with the gear JR2c.
The shaft JR2b of the roller JR2 is rotated so as to convey the leading end of the recording medium D2 back and forth. Further, the large-diameter portion Y1a of the first gear Y1 meshes with the second gear Y2, and the second gear Y2 is positioned laterally of the gear Y2 (above the plane of FIGS. 19 and 20). Attached third gear Y
3, and the third gear Y3 meshes with a fourth gear Y4 attached to the side of the gear Y3 (above the paper surface in FIGS. 19 and 20).

The fourth gear Y4 meshes with a fifth gear Y5 attached to the side of the gear Y4 (above the plane of FIGS. 19 and 20), and the fifth gear Y5 is
(To the left of the paper surface in FIGS. 19 and 20). The sixth gear Y6 meshes with a seventh gear Y7 attached to the side of the gear Y6 (in front of the paper surface in FIGS. 19 and 20).
7 is a large-diameter portion Y7a meshing with the sixth gear Y6 and a small-diameter portion Y on the long-side chassis HS2 side of the large-diameter portion Y7a.
7b. The small-diameter portion Y7b is attached to the end of the shaft portion JR1b of the paper feed roller portion JR1 and meshes with the gear JR1c so that the front end portion of the recording medium D2 is transported back and forth. The shaft JR1b is rotated.

Incidentally, on the side of the large-diameter portion Y7a of the seventh gear Y7 (above the plane of FIG. 3), the support projection ST1 is rotated integrally with the support projection ST1 in order to rotate the support projection ST1. A gear ST4 for connecting the gear ST3 and the large-diameter portion Y7a is provided, and the supporting projection ST1 winds the leading end of the wound recording medium D2 in response to the rotation of the step motor SN. Put it back or pull it out.

Thus, in this embodiment,
The springs SB1 and SB2, the switching lever KB, and the projection CP1 as the abutting member constitute the switching means, but are not necessarily limited to this aspect, and another aspect may be adopted.

Next, a control system of the tape printer 1 as an example of the recording apparatus will be described with reference to FIG. In FIG. 14, a control device CP of the tape printing apparatus 1 is configured with a central control device (hereinafter referred to as a CPU) as a core.
OM) and a readable / writable memory (hereinafter referred to as RAM). The motors SL, S
A drive control program for M and SN, a display program for displaying characters and the like input through each key of the keyboard 3 on the display 5, and other various programs necessary for the operation of the tape printer 1 are stored. The above C
The CG-ROM connected to the PU is a character generator for generating image data at the time of displaying or printing characters or the like. On the other hand, the RAM is provided with various data storage areas such as a display buffer and a print buffer, and this type of data is temporarily stored.

The motor drive circuits SLk, SMk, S
Nk is a circuit for driving the step motors SL, SM, SN. Further, the various sensors SQ described above,
As described above, SY, SE, SZ, etc.
The presence / absence of A, the presence / absence of the cassettes TC and RC, the types and widths of the recording media D1 and D2, the presence / absence of the recording media D1, and the like are detected, and the signals are sent to the CPU. The recording head H
D has a large number of heating elements formed in a row as described, and selectively drives each heating element via the CPU to generate heat on the recording media D1, D2 via the ink ribbon IR. Can print characters and the like.

Next, control for determining whether or not the line recording mode command matches the serial recording mode command based on the detection result of the detection sensor SQ by the control device CP will be described. That is, the detection sensor S as a detection device
Q discriminates between the tape cassette TC as the first cassette and the ribbon cassette RC as the second cassette, and the control device CP inputs a signal indicating the result of the detection, Input the operation signal. Therefore, as shown in FIG. 25, the control device CP determines whether or not a recording command has been issued to the tape station TS (step S1). That is, the control device CP determines whether or not the user has pressed the recording execution key at the tape station TS on the keyboard 3. Therefore, the control device CP forms a determination unit. If the tape station TS, that is, the recording execution key in the line recording mode is pressed, the control device CP determines in step S1 that YE
Judge as S. And the control device CP detects the detection sensor S
Based on the output signal of Q, the cassette R is placed on the carriage CA.
It is determined whether any one of C and TC is placed (step S2). Then, the control device CP determines whether or not the output signal from the detection sensor SQ matches the recording execution key in the line recording mode (Step S).
3). When a signal indicating that the cassette TC is placed on the carriage CA is input from the detection sensor SQ, the control device CP determines YES in step S3, and performs recording in the tape station TS, that is, recording in the line recording mode. Execute (step S4). Here, the control device CP
When a signal indicating that the cassette RC is placed on the carriage CA is input from the detection sensor SQ, NO is determined in step S3, and an error is displayed on the display 5 (step S5).

On the other hand, when the control device CP determines NO in step S1, it determines whether the wide station WS, that is, the recording execution key in the serial recording mode has been pressed (step S6). In this case, if the wide station WS, that is, the recording execution key in the serial recording mode is not pressed, the control device CP determines NO in step S6, and returns to step S1. When the wide station WS, that is, the recording execution key in the serial recording mode is pressed, the control device CP determines YES in step S6.

Then, the control device CP detects the detection sensor SQ
On the carriage CA based on the output signal of
It is determined whether any of C and TC is placed (step S7). The control device CP determines whether or not the output signal from the detection sensor SQ matches the recording execution key in the serial recording mode (step S8). Then, the control device CP controls the cassette RC on the carriage CA.
Is received from the detection sensor SQ, YES is determined in step S8, and the recording in the wide station WS, that is, the serial recording mode is executed (step S9). Here, when a signal indicating that the cassette TC is placed on the carriage CA is input from the detection sensor SQ, the control device CP determines NO in step S8 and displays an error on the display 5 (step S5). ). As described above, an error is displayed on the display 5 or, as another example, an error sound is emitted to notify the misplacement of the cassettes TC and RC mounted on the carriage CA. It can be replaced with the correct cassette TC, RC above.

As described above, the control device CP includes the detection sensor S
In order to determine whether the detection result of Q matches the line recording mode command based on the recording execution key on the keyboard 3 and the serial recording mode command, for example, the cassette TC may be erroneously used in the serial recording mode. Or the cassette RC is not erroneously used in the line recording mode. Further, in the case of this embodiment, the detection sensors SQ as the detection devices are the cassettes RC, TC
However, the present invention is not necessarily limited to this mode. As another detecting means, for example, the narrow recording medium D1 or the ink ribbon IR in the tape cassette TC used in the line recording mode may be used. Or at least one of the wide recording medium D2 used in the serial recording mode or the ink ribbon IR in the ribbon cassette RC.
You may make it detect. Also, the line recording mode command and the serial recording mode command are not necessarily
It is not necessary to output by the above key operation, and it may be output in other modes.

As described in detail above, according to the tape printer 1 of this embodiment, the recording head HD and the head transport means CH for reciprocating the recording head HD in the main scanning direction are provided. With the HD fixed
A line recording mode in which recording is performed on a narrow recording medium D1 using the ink ribbon IR; A recording apparatus having a serial recording mode for performing recording using the ribbon IR is performed. Then, the narrow recording medium D1 or the ink ribbon I in the tape cassette TC used in the line recording mode is used.
R, or at least one of the wide recording medium D2 used in the serial recording mode or the ink ribbon IR in the ribbon cassette IR. A control device CP is provided for determining whether or not the recording mode command matches the serial recording mode command. Thus, the tape printer 1 having the line recording mode and the serial recording mode is provided with good usability and low manufacturing cost.

The present invention is not limited to the above-described embodiment, and it is needless to say that various modifications and improvements can be made without departing from the gist of the present invention. For example, in the line recording mode, the first cassette TC storing the recording medium ID and the ink ribbon IR is used, and in the serial recording mode, the second cassette RC storing only the ink ribbon IR is used. However, the recording medium ID is not necessarily limited to this mode.
A cassette TC that stores only the information may be used. Also,
The ink ribbon IR stored in the second cassette RC does not need to be an ink ribbon to which a plurality of colors of ink are sequentially applied, and may be, for example, a single-color ink ribbon. Further, a motor other than the step motor may be used as the drive motor. Further, an ink medium other than the ink ribbon may be used.

Further, a step motor SL for transporting the recording medium D1 is used for pressing and separating the recording head HD and the recording medium D2 in the serial recording mode, or the recording is performed on the recording medium D2. It is a desirable mode to use the step motor SN for transporting the medium D2 for pressing and separating the recording head HD and the recording medium D1 in the line recording mode. It is not limited. Also,
The first platen P1 is formed in a cylindrical shape, and the second platen P2 is preferably formed such that a surface supporting the recording medium D2 is formed in a flat shape, but this is not essential.

The cassette HS0 (see FIG. 4) for holding the wide recording medium D2 in a wound state is, for example,
A feed roller may be provided inside the paper feed port. Further, the platen and the driving roller are, in the above-described embodiment,
Although they are separate members, they may be made of the same member.
Further, only one or both of the platen and the driving roller may be provided.

The recording apparatus of the present invention is not necessarily a tape printing apparatus. For example, in addition to a general thermal printer or the like, a heat-sensitive stencil sheet, a porous resin plate, or the like may be used as a recording medium. It may be a recording device used as a composition. Further, the recording head may be other than the thermal head.

[0117]

According to the recording apparatus of the first aspect, the fixed recording head is provided on the first recording medium by the first recording medium.
Recording can be performed in the line recording mode using the second ink medium. On the other hand, for the second recording medium, the recording head does not need to employ a rotating mechanism as in the related art. The recording medium can be reciprocated in the main scanning direction, and can be recorded on the second recording medium in the serial recording mode using the second ink medium. In this case, the determination unit is configured to determine at least one of the first recording medium or the first ink medium used in the line recording mode or the second recording medium used in the serial recording mode.
Since at least one of the recording medium and the second ink medium is detected, and it is determined whether the detection result matches the line recording mode command and the serial recording mode command, for example, The first recording medium or the first ink medium is not erroneously used in the serial recording mode, and the second recording medium or the second ink medium is not erroneously used in the line recording mode. Data can be correctly recorded on the first or second recording medium.

According to the recording apparatus of the present invention, in the line recording mode, at least the first cassette accommodating the first recording medium is used, and in the serial recording mode, the second cassette is used. Since the second cassette that stores only the ink medium is used, the second cassette does not store the recording medium and is compact.

According to the recording apparatus of the third aspect, since the first cassette further stores the first ink medium, the first ink medium is stored in the first cassette. In this case, the handling becomes easier as compared with the case where it is not stored.

Further, according to the recording apparatus of the present invention, there is provided a detecting device for discriminating between the first cassette and the second cassette, the detection result of the detecting device, the line recording mode command and the serial recording. Since the determination means determines whether or not the mode instruction matches, for example, the first cassette is erroneously used in the serial recording mode,
The second cassette can be correctly recorded on the first or second recording medium without being erroneously used in the line recording mode.

[Brief description of the drawings]

FIG. 1 is an external view of a tape printing apparatus which is an embodiment of a recording apparatus according to the present invention.

FIG. 2 is a front view showing the internal structure of the tape printer shown in FIG.

FIG. 3 is a plan view showing the internal structure of the tape printer shown in FIG.

FIG. 4 is a diagram showing a positional relationship between a wide recording medium and a recording head in the tape printing apparatus.

FIG. 5 is an enlarged front view showing a part of the tape station of FIG. 2;

FIG. 6 is an enlarged plan view showing a part of the tape station of FIG. 3;

FIG. 7 is an enlarged front view showing the tape cassette of this embodiment.

FIG. 8 is an enlarged front view showing the ribbon cassette of this embodiment.

FIG. 9 is an enlarged front view showing the carriage of this embodiment.

FIG. 10 is a side view of main components mounted on the carriage of FIG. 9 as viewed from the line II.

FIG. 11 is a side view of main components mounted on the carriage of FIG. 9, as viewed from the line II-II.

FIG. 12 is a side view of main components mounted on the carriage of FIG. 9 as viewed from the line III-III.

FIG. 13 is a side view of main components mounted on the carriage of FIG. 9 as viewed from the line IV-IV.

FIG. 14 is a block diagram illustrating a control configuration of the tape recording apparatus according to the embodiment.

FIG. 15 is an enlarged front view showing a state in which gears and the like are removed from the carriage in FIG. 9 and a state in which the recording head is pressed against a platen.

FIG. 16 is an enlarged front view showing a state in which gears and the like are removed from the carriage in FIG. 9 and a state in which the recording head is separated from a platen.

FIG. 17 is an enlarged front view showing a head drive cam gear of this embodiment.

18 is an enlarged front view showing a part of the head drive cam gear of FIG. 17 and a relation with the gear.

FIG. 19 shows conveyance of a wide recording medium according to the embodiment;
FIG. 3 is an enlarged plan view showing main components for pressing and separating a recording head and a first platen from each other.

FIG. 20 is a diagram illustrating conveyance of a wide recording medium according to the embodiment;
FIG. 3 is an enlarged plan view showing main components for pressing and separating a recording head and a first platen from each other.

FIG. 21 is a diagram showing a relative positional relationship when a recording head and a platen of this embodiment are pressed and separated from each other.

FIG. 22 is an exploded perspective view showing a transmission delay unit of this embodiment.

FIG. 23 is a front view showing another example of the operation member for separating the platen from the recording head according to the embodiment.

FIG. 24 is a diagram illustrating a relationship between movement of a carriage and a switching lever according to the present embodiment.

FIG. 25 is a flowchart showing an operation executed by the control device of the embodiment.

[Description of Signs] 1 Tape printing apparatus (recording apparatus) HD recording head P1 Platen (drive roller) CA carriage D1 Narrow recording medium (first recording medium) IR ink ribbon (first and second inks) Medium) D2 Wide recording medium (second recording medium) CH Carriage conveyance means SQ Detection sensor (detection device) TC Tape cassette (first cassette) RC Ribbon cassette (second cassette) 3 Keyboard CP controller (Determination means)

 ──────────────────────────────────────────────────の Continued on the front page (72) Inventor Jun Sugimoto Brother Industries, Ltd., 15-1 Naeshiro-cho, Mizuho-ku, Nagoya

Claims (4)

[Claims] A recording medium; a recording head; and a head transport unit configured to reciprocate the recording head in a main scanning direction. A line recording mode in which recording is performed on a recording medium, and a serial recording in which recording is performed using a second ink medium on a second recording medium while conveying the recording head in the main scanning direction. A first recording medium or a first ink medium used in the line recording mode, or a second recording medium used in the serial recording mode.
Detecting means for detecting at least one of the recording medium and the second ink medium, and discriminating whether or not the detection result matches the line recording mode command and the serial recording mode command. A recording device, characterized in that: 2. The recording apparatus according to claim 1, wherein in the line recording mode, a first cassette containing at least a first recording medium is used, and in the serial recording mode, a second ink medium is used. A recording apparatus using a second cassette for storing only the recording medium. 3. The recording apparatus according to claim 2, wherein the first cassette further stores a first ink medium. 4. The recording apparatus according to claim 2, further comprising a detection device for discriminating between the first cassette and the second cassette, a detection result of the detection device, a line recording mode command, and serial recording. A recording apparatus, wherein the determination means determines whether or not a mode command matches.