KR910006821B1 - Multicolour ribbon transfer system - Google Patents

Abstract

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Description

Multicolor ribbon changer

1 is a reduced plan view of one of the most suitable embodiment of the multicolor ribbon switching device according to the present invention.

2 is a front view of the device.

3 is a partial cross-sectional left side view showing an installation state for the print frame.

4 is an enlarged cross-sectional view taken along line IV-IV of FIG. 1;

5 is a rear view of the conversion plate.

6 is a cross-sectional view taken along line VI-VI of FIG. 5;

7 is a sectional view taken along line 9 of FIG.

8 is a cross-sectional view of a state in which the drive gear, the transmission lever, and the like are removed in FIG.

9 is a cross section through the transmission axis.

FIG. 10 is a sectional view taken along line 9 of FIG.

11 is an explanatory diagram showing a relationship between a multicolor ribbon and a printing element of the printing head.

12 is a relationship diagram showing the relationship between the drive gear and the cutting axis at the time of initial setting and the position of the drive gear corresponding to each ribbon shift position.

13 is a relationship diagram between the transfer lever and the transfer shaft at the time of initial value setting.

14 shows a relationship between the drive gear 18 and the transmission shaft in its initial position.

Fig. 15 is a relational diagram between the transfer lever and the transfer shaft in the initial position.

* Explanation of symbols for main parts of the drawings

1: Fraten 2: Print head

3: cassette 4, 5: ink ribbon

6: case 18: drive gear

The present invention relates to a multicolor printer using a ribbon cassette having a multicolor ribbon impregnated with different inks in a plurality of color bands divided in parallel in the longevity direction, wherein the multicolor ribbon is used to switch the color of the ribbon facing the print head. It relates to a switching device.

As an example of a multicolor ribbon switching device for serial printers, for example, British Patent Application No. 35407/78 is known. The device is fitted with a ribbon shift device and left mounted on the carriage of the print head for selectively placing one of a plurality of elongated color bands separated in the transverse direction of the multicolored ribbon between the print head and the platen. Set cam means associated with the cam follower of the ribbon shift device to set the ribbon shift device to convert the color band opposite the print head to the desired color in response to the position of the print head toward the margin, and before selecting a new shift position. And a reset cam means engaged with the cam follower of the ribbon shift device to reset the ribbon shift device. Thus, both cam means are fixedly arranged on the guide shaft of the carriage.

Moreover, it is also known that the ribbon base which supported the pair of ribbon spools which wound the ink ribbon was switched so that the color band which opposes the printing head of a ribbon by the combination of an electronic solenoid, a link, and a lever. (E.g., Japanese Patent Laid-Open No. 46-16057, Japanese Patent Laid-Open No. 53-82526).

In recent years, the dot printer has been widely used for office use for personal use. Therefore, the user is required to add a multi-color printing function as a condition to a general-purpose printer of black printing. However, any of the known multicolor ribbon switching devices as described above is dedicated to multicolor printing, and has a drawback in that the configuration is complicated, requires a large number of parts and a large installation space, and it has been practically impossible to meet the above requirements. .

In addition, in the first known technique, the reset cam means corresponds to the initial value setting mechanism, but the ribbon shift is a method of programmatically controlling the movement of the carriage toward the left end out of the printing area, thereby controlling the movement of the carriage. There is a drawback that is complicated and that the ribbon cannot be quickly shifted and switched. In the second known technique, the number of parts is large, the configuration is complicated, and assembly is cumbersome. Moreover, in the case of the multicolor ribbon switching device of such a structure, the detection switch for detecting the color band of the ribbon which opposes a printing head at the initial position is often used. At this time, when the detection switch is in the initial position of the multi-color ribbon switching device, the pedestal is usually disposed at a position where it can be engaged and opened. However, the arrangement of such a simple detection switch will cause the following problems. In other words, even if the detection signal is used only at the time of initial value setting, since the ribbon shift is frequently repeated during the printing operation, the detection switch is unnecessary, and moreover, the opening and closing is repeated frequently. In the case of using a mechanical switch such as a micro switch as the detection switch, the recovery of the contents of such a mechanical switch has its own limit, and thus the detection switch will end its life in a short time.

Again, in the case of a multicolor ribbon switching device like the first prior art, the inclination of the ribbon is rarely a problem because the exposure length of the ribbon is short from the ribbon cassette and the ribbon reciprocates with the print head. On the other hand, in the case of the type in which the ribbon cassette is mounted, the mounting spun of the ink ribbon is required beyond the reciprocating range of the printing head. Ink ribbons are usually formed in four color bands of black, blue, red, and yellow in parallel in the longevity direction, and the width of each color strip is considerably smaller than that of each color band of the two-color ink ribbon. In such a case, if the ribbon cassette is tilted inclined, for example, there is a possibility that adjacent color bands different from the desired color bands may face the printing heads depending on the moving position of the printing heads. The inclination of the ribbon cassette is caused by a slight degree of error in each component of the ribbon switching device or a slight tolerance in the connecting portion.

It is a first object of the present invention to provide a multicolor ink ribbon switching device that is most suitable for adding a multicolor printing function while being compact and inexpensive to manufacture.

Another object of the present invention is to provide a multicolor ribbon switching device capable of quickly switching a multicolor ribbon.

Another object of the present invention is to ensure sufficient durability of the detection switch by opening and closing only the detection switch for detecting the color band of the multicolored ribbon opposite the printing head in the initial position.

It is still another object of the present invention to eliminate or reduce the influence of some degree of error in each component part of the ribbon switching device or some tolerance in the connecting portion.

In the following, the most suitable embodiment of the present invention will be described by way of example with reference to the drawings.

In FIG. 1, the printing head 2 is arrange | positioned in front of the cylindrical platen 1. This printing head 2 is made to reciprocate along the axial direction of the platen 1 via the carriage (not shown) between the arm parts 3a and 3b of the ribbon cassette 3. Between the platen 1 and the printing head 2, a link ribbon 5 exposed from the arm 3a, 3b of the recording medium 4 and the ribbon cassette 3 is inserted. The ink ribbon 4 is endless, and most of it is folded and accommodated inside the cassette 3, and it runs so that it may run counterclockwise, for example by the ribbon drive device which is not shown in figure. In addition, this ink ribbon 5 has four color strips 5a to 5d divided in its longevity direction as shown in Figs. 2 and 3, and the color ribbons 5a to 5d. ), For example, are impregnated with black, blue, red, and yellow inks. On the front face 2a of the printing head 2, as shown in FIG. 11, printing elements 2b such as needles are arranged in a vertical line, and the color strips 5a of the ink ribbon 5 are arranged. ) To (5d) are opposed. 11 shows an initial state, and the black color strip 5a faces the printing element 2b. The switching of the color bands opposite the printing element 2b will be described in detail below.

The ribbon switching device of the present invention is unitized in this embodiment. As shown in FIG. 1, the case 6, 7 and the ribbon cassette 3 which face each other to the both sides of the ribbon cassette 3 in close proximity. Has a connecting bar 8 that extends along the rear side of the back panel and connects the casings 6 and 7. A stepping motor 9 as a drive motor is provided on the outer surface of the case 6, and the switching plate 10 moving up and down by the operation of the motor 9 is provided on the opposing surfaces of the cases 6 and 7, (11) is provided. Attaching hooks 3c to 3e protruding from both sides of the ribbon cassette 3 can be inserted into and detached from the shoulders of the switching plates 10 and 11. Accordingly, as the switching plates 10 and 11 move up and down, the ribbon cassette 3 placed horizontally between the switching plates 10 and 11 also moves up and down accordingly. The change of the color band of the ribbon 5 opposite to the printing element 2c shown in FIG.

The detailed structure of the switching plate 10 will be described with reference to FIGS. 4 to 6.

On the shoulder of the switching plate 10, as shown in FIG. 5 and FIG. 6, the attachment hooks 3c and 3e of the ribbon cassette can be detachably attached to the pawl hooks 10a and 10b and the mounting hooks. The recessed part 10c which can mount 3d is formed. Moreover, the elastic objective parts 10d, 10d, the guide pins 10e, 10e, and the hook 10f are integrally protruded and formed in the back part of the switching board 10, and the objective part 10d, ( 10d) and guide pins 10e and 10e are vertically aligned. As shown in Fig. 4, the guide pins 10e and 10e formed on the opposing surfaces of the case 6 are fitted with sliding materials, and the guest portions 10d and 10d are formed in the guide grooves ( By switching to the inner edge of 6a), the switching plate 10 is held against the opposite surface of the case 6. The hook 10f of the switching plate is movable in the groove 6b of the inner surface of the case 6, and is formed between the hook 6c and the hook 10f which are integrally formed at the lower end of the groove 6b. The spring 12 is latched. Therefore, the switching plate 10 is always pressed downward by the elasticity of the spring 12.

Next, a transmission mechanism for converting the rotation of the motor 9 into the vertical motion of the switching plate 10 will be described with reference to FIGS. 7 to 10.

In the case 6, as shown in FIGS. 7 and 8, a motor pinion 14 fixed to the output shaft 13 of the motor 9 enters and is formed integrally with the case 6. It meshes with the cogwheel 16 supported by the rotation of the shaft 15 freely. The pinion 17 formed integrally with the cogwheel 16 meshes with the teeth of the fan-shaped drive cogwheel 8. The drive gear 18 rotates reciprocally about the axis centerline of the transmission shaft 19 via the pinion 14, the gear 16 and the pinion 17 by the rotation of the motor 9, The rotational movement is transmitted to the transmission shaft 19. As shown in FIG. 9, the transmission shaft 19 is inserted in the concave portion 8a of the connecting bar 8 that connects the cases 6 and 7, and both ends thereof are disposed in the case 6. Rotation penetrates freely into (7). The transmission shaft 19 is formed in the non-circular cross-sectional shape, and the base of the drive gear 18 is relatively rotatably fitted to one end thereof. The drive gear 18 is 7th by the force spring 20 clamped between the hook 18a which protrudes in the back surface, and the hook 6c which protrudes in each part of the case 6. Is counterclockwise. Moreover, in the case 6, the transmission lever 21 which fits in a non-rotational direction with respect to the transmission shaft 19 is arrange | positioned near the front surface of the drive gear 18, and the long groove | channel of the front end part ( The guide pin 10e of the switching plate 10 is engaged with 21a).

Therefore, the rotational movement of the drive gear 18 is transmitted to the lever 21 via the transmission shaft 19, and moves the switching plate 10 up and down. On the rear face of the drive gear 18, a pressing piece 18b for opening and closing the micro switch SW for position detection of the ribbon 5 is integrally formed. As clearly shown in Figs. 8 and 9, the switch SW is directly driven by the drive gear 18, the transmission shaft 19, or the center of the projection 6d on the inner surface of the case 6. It is fixed to the adjustment lever 22 which can be rotated concentrically with the rotation center of the transmission lever 21. As shown in FIG. The adjustment lever 2 engages the rotational center and the concave arc groove 22a with the elastic length 6e which protrudes integrally from the inner surface of the case 6, thereby preventing rotation of the adjustment lever 22. In addition, the adjustment lever 22 is kept to the inner surface of the case 6. 3, 8, and 9, the outer surface of the case 6 is provided with an elastic head (with a cut groove cut out of the adjustment shaft 23) at a position opposite to the distal end of the adjustment lever 22 (FIG. 23a) is stuck. 6 f of cylinders are integrally formed in the inner surface of the case 6 so that the adjustment shaft 23 may be wrapped. On the inner circumferential surface of the cylindrical body 6f, a low let not shown is laid out, and the elastic arm 23b of the adjustment shaft 23 is engaged with this so that the adjustment shaft 23 can be held at a desired adjustment position. . Thus, the eccentric pin 23c protruding from the adjustment shaft 23 is engaged with the elongated groove 22b of the tip end of the adjustment lever 22. Thereby, the adjustment lever 22 can rotate about the protrusion 6d via the eccentric pin 23c, rotating the adjustment shaft 23, and pressurizing piece 18b of the drive gear 18. As shown in FIG. The positional relationship between the switch and the switch SW can be adjusted.

Next, the delivery mechanism in the case 7 will be described with reference to FIGS. 9 and 10.

The transmission lever 24 disposed in the case 7 has a cylinder portion 24b connected to the rear end via a U-shaped spring portion 24a, and the cylinder portion 24b is a transmission shaft 19. It is fitted so that rotation is impossible relative to the edge part of. The adjustment screw 25 which penetrates the projection part 24c which protrudes from the cylinder part 24b is stuck to the projection part 24d of the transmission lever side edge part of the spring part 24a, and this adjustment screw 25 is rotated. As a result, the opening amount of the U-shaped spring portion 24a is adjusted, and as a result, the position of the tip portion of the transmission lever 24 can be adjusted. The switching plate 11 facing the side of the case 7 has a symmetrical shape with the above-mentioned switching plate 10, and the same structure is held on the side of the case 7. That is, as shown in FIG. 10, the switching plate 11 uses the latching clasps 11a and 11b and the mounting clasp 3d which can attach | detach and detach | attach freely the attachment latch 3c, 3e of a ribbon cassette. The recessed part 11c is provided in the shoulder part. In addition, the elastic angle parts 11d, 11d, the guide pins 11e, 11e, and the hook 11f are integrally protruded from the back part of the switching board 10, and each part 11d, 11d is formed. ) And the guide pins 11e and 11e are vertically aligned. The guide pins 11e and 11e are freely fitted and fitted to the guide grooves 7a formed on the inner side of the case 6, and the corner portions 11d and 11d are formed of the guide grooves 6a. By switching on the inner edge, the switching plate 11 is kept in contact with the inner surface of the case 7. The hook 11f of the switching plate 11 can move in the groove 7b of the inner side of the case 7, and the hook 7c and the hook 11f formed integrally with the lower end of the groove 7b. The biasing spring 26 is latched in between. Therefore, the switching plate 11 is always urged downward by the elasticity of the spring 26. Since the guide pin 11e of the switching plate 11 is engaged in the elongate groove 24e formed at the distal end of the transfer lever 24, the transfer lever 24 is swung through the transfer shaft 19. The switchboard 11 moves up and down accordingly.

The multicolored ribbon switching device configured in the unit as described above is shown in FIG. 3 by the engaging hooks 27a and 27b integrally formed on the lower surfaces of the cases 6 and 7. As shown in FIG. Likewise, the attachment / detachment can be freely attached to a predetermined position of the printer frame 28 supporting the platen 1 or the like. Moreover, the connector 29 provided in the front end surface of the case 6 is for connecting the switch SW for position detection of the motor 9 and the ribbon 5 to a control circuit (not shown).

However, the transmission levers 21 and 24 have a small tolerance with respect to the drive shaft 19 between the transmission levers 21 and 24 at both ends of the drive shaft 19 due to manufacturing errors of individual components. It is not limited to tolerance. In addition, when the drive shaft 19 has a long space | interval like this embodiment, this drive shaft 19 itself may bend. Accordingly, these causes the height positions (positions in the vertical direction) of the left and right switching plates 10 and 11 to be different. As a result, the ribbon cassette 3, that is, the ink ribbon 5, is inclined with respect to the moving direction of the printing head 2, but this inclination rotates the adjusting screw 25 by an appropriate amount, thereby making the U-shaped spring portion 24a. Is adjusted to be parallel to the moving direction of the printing head 2 by adjusting the amount of opening.

Next, the initial value setting of the multicolor ribbon switching device of the present invention will be described.

When printing is performed in the respective colors of black, red, blue, and yellow, the drive gear 18 is located at positions P ₁ to P ₄ in FIG. 12, respectively. The angles between the P ₁ position, the P ₂ position, the P ₂ position and the P ₃ position, and the P ₃ position and the P ₄ position are Q ₁ , Q ₂ and Q ₃ . In this embodiment, the P ₁ position is the initial position, and at this time, the black color band 5a faces the printing head 2. In the ribbon shift for color switching during the printing operation, the driving gear 18 has a total angle θ of the angles Q ₁ , Q ₂ , Q ₃ (the first angle that the total angle θ defines in the claims). Reciprocating rotation in the range).

Initial value setting is performed at the time of power supply to a printer as an example. At this time, although the drive gear 18 is in any position of P ₁ to P _4, the drive gear 18 is rotated clockwise to the P ₀ position in FIG. 12 at any position. The position P ₀ is a position shifted clockwise by the angle θ ₀ from the position P ₁ , but the detection switch SW is closed by the pressing piece 18b of the drive gear 18 at this position P ₀ . In addition, this angle (theta) ₀ corresponds to the 2nd angle prescribed | regulated in the claim.

In this embodiment, in order to keep the transfer cassette 21 floating and to keep the ribbon cassette 3 stationary even if the drive gear 18 is displaced from the P ₁ position to the P ₀ position or vice versa. Tolerances are actively used in the fitting portion between the drive gear 18, the transmission shaft 19, and the transmission shaft 19 and the transmission lever 21 as follows.

As clearly shown in FIGS. 12 to 15, the shaft hole 18c and the transmission shaft 19 of the drive gear 18 and the shaft hole 21b and the transmission shaft 19 of the transmission lever 21 are shown. There is always a minimum tolerance between), which allows for relative angles that make up the angles β ₁ , β ₂ .

14 and 15 show the drive gear 18 and the transmission shaft at the initial position (the ribbon cassette 3 is located at the lowest position) in which the black color band 5a faces the printing head 2. (19) and the relative positional relationship between the transmission shaft 19 and the transmission lever 21 are shown. Since the drive gear 18 is biased counterclockwise by the biasing spring 20 shown in FIG. 7, the drive gear 18 and the transmission shaft 9 when it is in the initial position shown in FIG. The angle between) becomes as shown. In addition, as shown in FIG. 4, the transmission lever 21 is added clockwise to FIG. 15 via the guide pin 10e of the switchboard 10 which is biased downward by the spring 12, and is shown in FIG. Therefore, an angle as shown in FIG. 15 is caused between the transfer lever 21 and the transfer shaft 19.

Therefore, when the drive cogwheel 18 is rotated clockwise in FIG. 14 via the drive motor 9 for setting the initial value, the transmission shaft (where the drive cogwheel 8 is rotated by an angle β ₁ ) 19 follows the rotation of the drive gear 18. The transmission shaft 19 is then rotated by an angle β2 thereafter, but only revolves the shaft hole 21b of the transmission lever 19 and the transmission lever 21 remains stationary. Where the drive gear 18 has rotated by the angle β1 + β2 = θ ₀ , the detection switch SW is closed (solid state in FIG. 12), but the transmission lever 21 keeps the stopped state. The initial value setting signal of the detection switch SW at this time is supplied to the control circuit. After closing the detection switch SW, the motor 9 is rotated back until the state shown in FIG. 14 is again shown. Thus, even if the drive gear 18 rotates from the P ₁ position to the P ₀ position and vice versa for the initial setting, the transmission lever 21 continues to stop, and the ribbon cassette 3 also has the lowest value. The location is intact.

In addition, the above embodiments are only illustrative examples of the most suitable embodiments of the present invention, and various modifications may be made without departing from the technical spirit of the present invention. For example, the present invention also includes a configuration in which the transfer lever 21 moves at the time of setting the initial value such that each β ₁ , β ₂ is small or close to zero.

According to the multicolor ribbon switching device of the present invention described in detail above, a pair of cases are arranged opposite to both end portions of the multicolor ribbon cassette, and both cases are connected at a connecting bar, and the upper and lower sides of the two cases are connected to each other. The ribbon is installed by moving or swinging the drive plate, and the transfer bar for interlocking the mechanisms in both cases is connected to both sides of the multi-color ribbon cassette by the transfer bars so that the color bands of the ribbon can be switched. The switching device can be compactly configured, and the configuration is simplified and easy to assemble. Since the ribbon switching device can be installed in the form of a source, the multi-color printer can be miniaturized. In addition, it can easily respond to the user's request to add a multi-color printing function, moreover, can be provided at a low price.

In addition, the switching of the multicolored ribbon can be quickly performed, and furthermore, the detection switch for position detection of the ribbon is not opened or closed at the time of the normal ribbon shift, and is opened and closed only at the initial value setting, thus ensuring sufficient durability. This provides a multicolor ribbon switching device with low failure and high reliability.

In addition, since the level adjustment device of the ribbon cassette is added, the inclination of the ribbon can be eliminated without requiring the improvement of the individual parts accuracy, and since this adjustment device is very simple in configuration, it can be performed in a low space with low cost. There is a number.

Claims (7)

First and second cases disposed opposite both ends of the multicolor ribbon cassette having a multicolor ink ribbon having a plurality of color bands partitioned in parallel in the longevity direction, and connecting bars connected to both cases, The first and second switching plates capable of supporting the multi-colored ribbon cassette and both ends are freely mounted on each of the opposing surfaces of the first and second cases, and the drive motor and its rotation are mounted on the first case. A first transmission mechanism in which the first switching plate is linked to move so that any one of the color bands of the ribbon cassette faces the printing head, and a transmission shaft driven through the first transmission mechanism. An end thereof enters the first and second cases past the connecting bar, and moves the second switching plate to the second case in conjunction with the transmission shaft. Multi-color ribbon switching device, characterized in that the second transmission mechanism is installed. The multicolor ribbon switching device according to claim 1, wherein the first and second cases are detachably attached to the printer frame. The second transmission mechanism of claim 1, wherein the first transmission mechanism is rotated in the range of the first angle by the drive motor, and the second transmission mechanism has exceeded the range of the first angle at the time of initial value setting. A drive gear that is rotated to an angle position, a transmission shaft that is rotated in a non-rotational manner relative to the drive gear; And a transmission lever for moving the gears, and when the initial value is set, the drive gear is opened and closed by the drive gear when the drive gear is rotated to the position of the second angle beyond the range of the first angle. And a detection switch for detecting the color band of the multi-colored ribbon facing the printing head. 4. The method according to claim 3, wherein the second angle is substantially equal to or slightly less than each of the angles caused by the tolerances at the fitting portions of the drive gear and the transmission shaft and the transmission shaft and the transmission lever. The multicolor ribbon switching device characterized by the above-mentioned. The multicolor ribbon switching device according to claim 3 or 4, wherein the drive gear is a sector gear. 4. The multicolor ribbon switching device according to claim 3, wherein the detection switch is provided on an adjustment lever which can be rotated about the rotation center of the drive gear. 4. The multicolor ribbon switching device according to claim 3, wherein a U-shaped spring portion is integrally formed on at least one of the transfer levers, and an adjustment screw for adjusting the opening amount thereof is screwed in the U-shaped spring portion. .

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