JPH1058807A - Heat punching apparatus for stamp body - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a heat punching apparatus for a stamp body preventing a thermal head from continuous pressurizing a printing surface part, avoiding an ink contamination in a heat punching apparatus after completion of a punching action. SOLUTION: In a punching process, firstly a dot pattern data for punching is prepared based on a format input in an input buffer and a character string data for punching. Thereafter, a carriage feed motor is driven, a carriage 87 moves from a position indicated in a full line to a position indicated in a two- dot chain line and a thermal head 90 is driven, a punch based on a dot pattern data for punching is formed on a printing surface part. The carriage feed motor is continuously driven even after completion of punching to move and drive the carriage 87 to the position of a thermal head 90 indicated in a two-dot chain line from the print surface pat to the outside of the left, whereby the print surface part is pressurized, an ink leakage does not occur at the thermal heat 90.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat punching apparatus for a stamp body, and more particularly to a heat punching apparatus for a stamp body having a stamp face made of a heat-sensitive stencil sheet and forming a hole in the stamp face.

[0002]

2. Description of the Related Art Heretofore, various stamps for printing a company name, an address, and other various character strings on the surface of a sheet, in which a stamp face portion is made of rubber, have been used. This type of stamp is expensive because the stamp is usually created individually according to the order, and the period from order to acquisition is long.

On the other hand, conventionally, a desired pattern can be pierced by irradiating infrared rays or a thermal head, and by penetrating ink from a group of perforations, it can be used for printing various patterns such as character strings, figures, and marks. Heat-sensitive stencil paper has been put to practical use.

The applicant of the present application has disclosed in Japanese Utility Model Laid-Open Publication No. Hei 5-74833 a stencil printing plate mainly comprising the heat-sensitive stencil sheet and an impregnated body impregnated with ink. A stencil printing plate suitable for making a stamp instead of a rubber stamp was proposed.

[0005] This stencil printing plate is obtained by adhering an impregnated body impregnated with ink to a synthetic resin film and a frame surrounding the impregnated body. The stencil sheet is bonded.

When the stencil printing plate is applied to a stamp, the stencil printing plate is bonded to the lower surface of the base of the stamp member having a grip portion via a cushion material, and the heat-sensitive stencil printing paper is irradiated with infrared light or the like. If a pattern such as a desired character string is pierced by a thermal head, the stamp is composed of a stamp member and a stencil printing plate. A stamp is obtained that can be printed over and over.

[0007] Further, the applicant of the present invention has disclosed in
In Japanese Patent Publication No. 78, a stamping device comprising a stamp body and a heat punching device for forming a hole in the stamp face of the stamp body was proposed.

[0008] The stamp body includes a gripping portion, a main body case, a supply reel and a take-up reel which are provided in the main body case, and supply and take up a tape-shaped heat-sensitive stencil sheet.
An ink pad for supplying ink to the perforated heat-sensitive stencil sheet.

The heating perforation apparatus includes a perforation mounting portion for detachably mounting a stamp body, a feed mechanism for feeding a thermosensitive stencil sheet of the stamp body, and a perforation in the thermosensitive stencil sheet of the stamp body. It is composed of a thermal head, a keyboard for inputting characters and symbols, and a control device for controlling a feed mechanism and a thermal head so as to pierce a heat-sensitive stencil sheet with a character string input based on input data. ing.

According to the stamping apparatus, a tape-shaped heat-sensitive stencil sheet is provided on the stamp body, and a desired character string pattern can be perforated on the stamp face of the stamp body by the heating perforating apparatus. Therefore, different patterns can be perforated on the stamp surface, and at the time of printing, ink is automatically supplied from the ink pad inside the stamp body to the stamp surface, so that external ink is applied to the stamp surface. Can be printed without the need.

[0011]

In the above stamp apparatus, the heating and punching apparatus presses the thermal head against the stamp face of the stamp body while moving the thermal head from a predetermined initial position in a certain direction. A desired stamp surface pattern composed of a character string or the like is formed by selectively performing heat perforation.

However, in the conventional stamp device,
The thermal head is driven only for the input stamp data, and after driving the punch for the stamp data, the thermal head is stopped immediately. Therefore, depending on the size of the stamp surface content input and set by the operator, the thermal head may stop while being located in the middle of the stamp surface of the stamp body. Then, since the thermal head presses down on the stamp surface, if the thermal head is left as it is, the ink of the ink pad may leak from the pattern on the heat-sensitive stencil sheet perforated by the pressing force of the thermal head. as a result,
The perforating mechanism including the thermal head and the internal mechanism of the heating perforating apparatus are contaminated with ink.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has been made in a heating and punching apparatus including an ink adhering to a thermal head due to leaving a stamp body after a punching operation. An object of the present invention is to provide a heat punching device for a stamp body that can prevent ink contamination.

[0014]

In order to achieve this object, a heat punching apparatus for a stamp body according to the present invention according to the first aspect of the present invention has a stamp in which ink is contained and a stamp face portion is formed by a heat-sensitive stencil sheet. A hole for detachably mounting the body, a thermal head for perforating the stamp surface portion of the stamp body attached to the hole mounting portion in a dot shape, and perforating the stamp surface portion by the thermal head. When the operation is completed, there is provided a separation unit that relatively quickly separates the thermal head from the stamp surface.

According to a second aspect of the present invention, there is provided a heat punching apparatus for a stamp body according to the first aspect of the present invention, further comprising: Driving means for performing a punching operation from one end of the stamp surface of the stamp body to the other end while moving the thermal head in parallel to the thermal head. The head is moved in the direction of the other end to a position away from the stamp surface.

In the heat punching apparatus for a stamp body according to the first aspect of the present invention, when the stamp body is mounted on the mounting portion for punching of the heat punching apparatus, the thermal head perforates the stamp face of the stamp body in a dot shape. I do. When the perforating operation is completed, the separating means promptly relatively separates the thermal head and the stamp surface of the stamp body to a position where they are separated from each other.

By doing so, it is possible to prevent the thermal head after the punching operation has been completed from being left unattended while keeping the stamp surface pressed.

According to a second aspect of the present invention, in addition to the above-described operation, the driving means is arranged so that the drive means extends in the longitudinal direction of the stamp face of the stamp body mounted on the perforated mounting portion. While moving the thermal head in parallel to the stamp body, a punching operation is performed from one end to the other end of the stamp surface of the stamp body. Is moved in the direction of the other end as it is to a position away from.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

The heating and punching apparatus 50 according to the present embodiment
This is a device for heat-perforating the stamp face portion 33 of the stamp body 1 shown in FIGS. 1 to 10, and a specific configuration is shown in FIGS.

First, regarding the stamp body 1, FIG.
This will be described with reference to FIGS.

As shown in FIG. 1 to FIG.
Is a grip portion 2 for grasping by hand, a stamp portion 3 fixedly connected to the grip portion 2, a skirt member 6 for covering the outer peripheral side of the stamp portion 3, and a detachably attached to the stamp portion 3. And a protective cap 7.

The grip portion 2 is formed of a rectangular parallelepiped hollow body made of a metal or a synthetic resin material and having an open lower end, and a concave portion 11 for sticking a label 10 is formed at the top thereof. At the lower ends of the front wall 12 and the rear wall 13, a pair of engaging claws 14 protruding downward are provided, respectively. In addition, on the lower part of the front wall 12 and the rear wall 13 of the gripper 2,
A guide groove 15 is formed, an engagement recess 16 is formed in the front wall 12, an engagement hole 18 is formed in the left side wall 17, and a central portion of a lower surface of the upper wall 19 inside the grip portion 2 is provided. A spring support 20 is formed.

The stamp section 3 includes a stamp section main body 4
The stamp portion main body 4 is inserted and fixed from below, covers the upper approximately 2/3 portion of the outer periphery of the stamp portion main body 4, and engages with the four engaging claws 14 of the grip portion 2 to hold the grip portion. 2
And an outer peripheral holding member 5 fixed to the outer periphery.

The stamp body 4 has a rectangular parallelepiped hollow synthetic resin base member 2 having a shallow recess 25 on the lower surface side.
6, an impregnated body 27 (corresponding to an ink body) mounted in the recess 25 of the base member 26 and impregnated with oil-based ink, and an adhesive 29 covering the lower surface of the impregnated body 27 and the outer peripheral side of the base member 26. And a heat-sensitive stencil sheet 28 adhered to the outer peripheral surface of the base member 26. The impregnated body 27 may be bonded to the concave portion 25 of the base member 26 with an adhesive or the like.

The base member 26 is made of a synthetic resin material (eg, vinyl chloride, polypropylene, polyethylene, polyacetal, polyethylene terephthalate, etc.) or a metal material which is excellent in oil resistance due to contact with oil-based ink. By mounting the impregnating body 27 in the concave portion 25 of 26, the displacement of the impregnating body 27 can be prevented, and the outflow of ink from the impregnating body 27 can be prevented.

The impregnated body 27 is made of a resilient foam or non-woven fabric of a synthetic resin material (eg, polyethylene, polypropylene, polyethylene terephthalate, polyurethane, acrylonitrile butadiene rubber, etc.).
The impregnated body 27 is impregnated with oil-based ink in a saturated state, and when pressure is applied to the impregnated body 27, the ink oozes out.

As shown in FIG. 6, the heat-sensitive stencil sheet 28 comprises a thermoplastic film 30, a porous support 31,
And an adhesive layer 32 for adhering them. The thermoplastic film 30 is made of a thermoplastic synthetic resin material (for example, polyethylene terephthalate, polypropylene, or vinylidene chloride) having a thickness of 1 to 4 μm, preferably 2 μm.
(A vinyl chloride copolymer).

Those having a thickness of less than 1 μm are impractical because of their high manufacturing cost, weak strength and lack of practicality.
Those having a thickness of 4 μm or more cannot be perforated with a general thermal head having a rated output of about 50 mJ / mm 2 because the thickness is too large.

The porous support 31 may be made of natural fibers (for example, manila hemp, crocodile, Mitsumata, etc.), synthetic fibers (for example, polyethylene terephthalate, polyvinyl alcohol, polyacrylonitrile, etc.), or semi-synthetic fibers such as rayon. The main material is a porous thin paper.

As shown in FIGS. 5 and 7, with the base member 26 turned upside down, the impregnating body 27 is attached to the concave portion 25, and then the impregnating body 27 is impregnated with the oil-based ink. 27, a heat-sensitive stencil sheet 28 is placed on the impregnated body 27 so that the porous support 31 is on the impregnated body 27 side, and the heat-sensitive stencil sheet 28 is adhered to the surface of the impregnated body 27. The outer peripheral side portion is tightly folded on the outer peripheral surface of the base member 26 and adhered by the adhesive layer 29 to form the stamp portion main body 4 shown in FIG.

The portion of the heat-sensitive stencil sheet 28 that is in close contact with the surface (the lower surface in FIG. 5) of the impregnated body 27 constitutes the stamp face portion 33. As described above, since the outer peripheral portion of the heat-sensitive stencil sheet 28 is adhered to the outer peripheral surface of the base member 26, the stamp surface portion 33 covering almost the entire lower surface of the stamp portion 3 is adopted.
Could be formed. As a result, positioning for printing is simplified.

The outer peripheral portion of the heat-sensitive stencil sheet 28 is
In order to adhere to the outer peripheral surface of the base member 26, heat-sensitive stencil paper 2
8, an adhesive layer 29 may be previously formed on the outer peripheral surface of the base member 26, or the adhesive layer 29 may be formed on the outer peripheral surface of the base member 26 in advance, or a heat-sensitive stencil Base paper 28
The adhesive layer 2 is applied to both the outer peripheral portion of the base member 26 and the outer peripheral surface of the base member 26.
9 may be formed in advance.

As shown in FIGS. 2 to 4, the outer peripheral holding member 5 includes a peripheral wall portion 34 having a rectangular shape in plan view to which the stamp portion main body 4 is adhered in an inner shape, an upper wall portion 35, and an upper wall portion 35. Wall 35
And a pair of left and right engaging wall portions 36 projecting from the predetermined height. An engagement hole 37 corresponding to the four engagement claws 14 of the grip portion 2 is formed in the pair of left and right engagement wall portions 36, and the pair of left and right engagement wall portions 36 are provided on the skirt member 6. The four engaging claws 14 are inserted into the pair of left and right rectangular holes 42 of the wall 41 so as to be slidable vertically from below, and the four engaging claws 14 are engaged with the four engaging holes 37 of the engaging wall 36 from above. The outer peripheral holding member 5 is fixed to the grip 2 by bringing the upper end of the engaging wall 36 into contact with the lower end of the grip 2.

As shown in FIGS. 2 to 4, the skirt member 6 has a rectangular outer peripheral wall portion 40 in a plan view in which the outer peripheral wall portion 34 of the outer peripheral holding member 5 is slidably fitted vertically.
An upper wall portion 41 located above the upper wall portion 35 of the outer peripheral holding member 5 at the upper end thereof, and holding the upper wall portion 41 by projecting upward from the center of the upper wall portion 41 by a predetermined height. It comprises a portal 43 inserted into the section 2 and a spring support 45 projecting from the center of the upper end of the portal 43.

Below the left and right walls of the gate 43,
A guide hole 44 is formed at a position in the front-rear direction corresponding to the guide hole 18 so as to penetrate both wall portions.

A compression spring 21 for urging the skirt member 6 downward with respect to the grip portion 2 is mounted on the spring support portion 20 of the grip portion 2 and the spring support portion 45 of the skirt member 6. 6 is configured to be able to move up and down over a first position shown in FIGS. 3 and 4, a second position shown in FIG. 9, and a third position shown in FIG. 8. It is biased toward the first position. The lower end of the center of the four surfaces of the outer peripheral wall 40 of the skirt member 6 is partially cut away for attaching and detaching the protective cap 7 and positioning the stamp face portion 33.

In the first position, the upper wall portion 41 of the skirt member 6 comes into contact with the upper wall portion 35 of the outer peripheral holding member 5, so that the lower end of the skirt member 6 projects lower than the stamp surface portion 33. When in the second position, the upper wall portion 41 of the skirt member 6
When the lower end of the skirt member 6 is located at the same level as the stamp face portion 33 and is located between the upper wall portion 35 of the outer peripheral holding member 5 and the lower end of the grip portion 2, the skirt member 6
The upper wall portion 41 is in contact with the lower end of the grip portion 2, and the lower end of the skirt member 6 is located above the stamp surface portion 33. still,
It is desirable that the stroke of the skirt member 6 from the first position to the second position be set to about 5 mm.

The protective cap 7 is attached to the stamp body 4
The outer peripheral wall portion 48 is formed in the same shape as the outer peripheral wall 34 of the outer peripheral holding member 5 in a plan view, and the protective cap 7 is made of a skirt. It is supported by being fitted inside the outer peripheral wall portion 40 of the member 6.

As shown in FIGS. 3 and 4, the protective cap 7
In the state in which the outer peripheral wall 34 is attached, the upper end thereof abuts against the lower end of the outer peripheral wall 34, and a small gap is left between the protective cap 7 and the stamp face 33. It is supported by a frictional force between the outer peripheral wall portion 40 and the inner peripheral surface. Therefore, even if the grip portion 2 is pushed downward with the protective cap 7 attached, the gap is maintained by the contact between the upper end of the protective cap 7 and the lower end of the outer peripheral wall 34, so that the protective cap Ink does not adhere to 7.

As shown in FIG. 10, for example, as shown in FIG. 10, a large number of perforations of a pattern consisting of a character string of a mirror character of "Brother Kogyo Co., Ltd." (Dot pattern perforation) is formed by a thermal head of a thermal printer (not shown).
Since a stamp body capable of printing a character string of "Brother Industry Co., Ltd." which is a mirror image of the pattern and a six-fold rectangular frame is configured, similar to a stamp having a normal rubber stamping surface, for example, The pattern can be printed about 1000 times. In addition, it is a matter of course that the holes can be formed by infrared irradiation in addition to the holes formed by the thermal head.

In the case of perforating the heat-sensitive stencil sheet 28 constituting the stamp face portion 33, the stamp body 1 is set on a perforation mounting portion 71 of a heating perforation device 50 described later, and a guide bar 83 of the device is set. 3 and 4, the skirt member 6 is held at the third position to perform perforation by inserting the skirt member 6 through the guide holes 18, 44, 44, and the protective cap 7 is attached when not in use. As shown in FIG. 7, the skirt member 6 is held in the first position, and when printing, the protective cap 7 is removed, the skirt member 6 is held in the first position, and the printing position on the surface of the sheet is to be printed. After the skirt member 6 is positioned, the stamp surface portion 33 of the stamp portion 3 is positioned, and then the grip portion 2 is pressed downward to print as shown in FIG.

Next, a heating perforation apparatus 50 according to an embodiment of the present invention will be described.

As shown in FIGS. 11 to 15, the heating and punching apparatus 50 includes a main body frame 51, a keyboard 52 provided on a front portion of the main body frame 51, and a liquid crystal display 5.
3, a heating perforated portion 54 provided at a rear portion of the main body frame 51, a control unit 110 provided in the main body frame 51, and the like.

The keyboard 52 includes a character / symbol key 56 including a plurality of character keys and a plurality of symbol keys which also serve as a kana key, an alphabet key, and various function keys (a cursor movement key 57, an execution key 58, a line feed key 5).
9, Confirm / End key 60, Cancel key 61, Delete key 6
2, a shift key 63, a small letter switch 64, a character type setting switch 65, a punching switch 66, etc.) and a main switch 67.

The liquid crystal display 53 is configured to display a plurality of lines of character strings corresponding to a pattern to be printed on the stamp body 1.

Next, the heating hole 54 will be described.

As shown in FIGS. 13 to 22, the heating perforated portion 54 includes a sub-frame 70, a perforated mounting portion 71 for detachably mounting the stamp body 1, and a perforated mounting portion 71. A heating perforation mechanism 72 and the like for perforating the stamp surface 1 of the mounted stamp body 1 in a dodged shape are provided.

14 to 17, the right side wall 73 of the sub-frame 70 is provided with the lower half of the stamp body 1 in which the width of the stamp portion 3 in the front-rear direction is the largest. An opening 74 having substantially the same shape as the side surface is formed. A sector gear 76 is fixedly provided on an opening / closing door 75 that opens and closes the opening 74. The opening / closing door 75 and the sector gear 76 are connected to each other by a pivot 77 oriented in the left-right direction in FIG. It is pivotally attached to the right side wall 73 so as to be freely rotatable. A pair of front and rear parallel guide members 7 are provided on the upper part of the sub-frame 70.
8 and 79 are provided at the lower ends of these guide members 78 and 79.
Are formed opposite to each other.

A pair of left and right rollers 81 are provided on the front guide member 78 via a long hole so as to be movable in a short distance in the front-rear direction in FIG. 16. These rollers 81 are urged rearward by a spring 82. ing.

The guide bar 83 fixed to the front guide member 78 is disposed at an intermediate position between the guide members 78 and 79. As shown in FIGS. A taper surface 84 inclined downward to the right is formed, and a locking portion 85 that regulates the left limit position of the stamp body 1 is formed at the left end of the guide bar 83.

The stamp body 1 is inserted through the opening 74,
In a pair of guide grooves 15 before and after the holding portion 2 of the stamp body 1,
The stamp body 1 is supported by the pair of guide sections 80 by engaging the pair of front and rear guide sections 80, and the stamp body 1
The position of the stamp body 1 is accurately set by being urged backward by a spring 82 via a pair of rollers 81, the stamp body 1 abuts the locking portion 85, and the right roller 81 is The stamp body 1 is engaged with the engagement recess 16 of the stamp body 1.
The left and right positions are set accurately.

When the stamp body 1 is mounted on the mounting portion 71 for drilling, the guide bar 83 is inserted through the guide holes 18, 44, 44 of the stamp body 1, whereby
The skirt member 6 is held in a state where it is raised to the third position shown in FIG.

The heating perforation mechanism 72 will be described. As shown in FIGS.
1, a guide rod 88 extending in the left-right direction for guiding the carriage 87 over the right end wall 73 and the left end wall 86 of the sub-frame 70, and the carriage 87 is guided and mounted on the carriage 87. A head switching rod 89 extending in the left-right direction for operating a cam body 91 for switching the position of the thermal head 90 is mounted. The cam body 91 is mounted on the head switching rod 89 so as to be non-rotatable and slidable in the axial direction. Have been.

The carriage 87 includes a guide rod 88
The head 87 and the head switching rod 89 are movably supported in the left-right direction. At the front end of the carriage 87, a rack 92 having a predetermined length is formed over its entire length.

The carriage 87 has a cam contact plate 93.
And a head heat radiating plate 94 are attached to the head heat radiating plate 94 so as to be swingable up and down by a support shaft 95 oriented in the front and rear direction.
The thermal head 90 is fixed, and the head radiating plate 94
A spring 97 mounted on a pin 96 fixed thereto.
Thereby, the cam contact plate 93 is elastically urged upward.

The cam body 91 is formed in an elliptical shape and is brought into contact with the lower surface of the cam contact plate 93. When the head switching rod 89 is rotated to bring the cam body 91 to the horizontal position, the thermal head 90 When the cam body 91 is placed in an upright posture together with the head heat radiating plate 94 and the cam body 91 is in the vertical position, the thermal head 90 is swung upward via the cam contact plate 93 and the spring 97 to be switched to the piercing position. .

At the right end of the head switching rod 89, a gear 98 meshing with the sector gear 76 is provided outside the right end wall 73 of the sub-frame 70.
When the door 5 is opened, the cam body 91 is in the horizontal posture, and when the door 75 is closed, the cam body 91 is switched to the vertical posture.

On the front wall 99 of the sub-frame 70, a stepping motor 100 for driving a carriage 87,
A drive gear 101 meshed with the rack 92 and a reduction gear mechanism 107 for transmitting rotation of the output gear 102 of the output shaft of the stepping motor 100 to the drive gear 101 are additionally provided. Therefore, since the rotational driving force of the stepping motor 100 is transmitted to the drive gear 101 at a reduced speed, the carriage 87 can be driven to move in the left-right direction by the stepping motor 100.

The thermal head 90 is similar to the thermal head of a thermal printer. As shown in FIG. 23, the thermal head 90 has, for example, 96 heating elements 103 arranged in a line in the front-rear direction. Is provided.

Next, a control system including a control unit 110 for controlling the driving of the heating perforation mechanism 72 and the liquid crystal display 53 will be described.

As shown in FIG. 22, the control unit 110
Includes a keyboard 52, a thermal head 90, a carriage feed motor 100, a liquid crystal display 53,
Two proximity switches 104 and 105 for detecting the presence / absence of the stamp body 1 and the front / rear width are connected.

In the case of the present embodiment, the stamp body 1 has two types, a narrow type shown by a solid line in FIGS. 15 and 19 and a wide type shown by a chain line. 13, 15, and 19, the plate piece 10 fixed to the lower surface of the rear guide member 79.
6, the proximity switches 104 and 105 detect the wide stamp body 1, and the proximity switch 104 detects the narrow stamp body 1.

As shown in FIG. 22, the control unit 110
CPU 111, ROM 112, RAM 113
A CG-ROM 114 for drilling, a CG-ROM 115 for display on the display 53, an input interface 116 connected to the keyboard 52 and the proximity switches 104 and 105, and an output interface 117. Are interconnected by a bus 118. Further, the control unit 110 has a head driving circuit 119 connected to the output interface 117, respectively.
, Motor drive circuit 120, display drive circuit 1
21 are provided.

The ROM 112 is provided with a program memory 122 in which a control program for controlling the entire operation of the heating and punching apparatus 50 is stored, and a dictionary memory 123 for kana / kanji conversion and the like.

The RAM 113 is provided with an input buffer 124 for storing input data, a punching buffer 125 for storing punching data, a shift register 126, and various other counters and registers.

In the CG-ROM 114 for punching, dot pattern data of a number of characters to be punched are stored in association with the code data.
In M115, display dot pattern data of a large number of characters to be punched are stored in association with code data.

Next, the head drive circuit 119 will be described.

As shown in FIG. 23, one electrode of each heating element 103 is connected to a +12 V power supply terminal 127, and the other electrode is connected to a driver 128.

The input terminals of each driver 128 include an output terminal of an inverter 129 connected to the input side of a strobe input terminal 130 for punching, and an output terminal of a data latch circuit 132 whose input side is connected to a latch signal input terminal 131. Terminals are connected to each other.

Further, each input terminal of the data latch circuit 132 has a clock input terminal 133 and a data input terminal 13.
4 and the output terminals of the shift register 135 whose input terminals are connected to each other.

In the head driving circuit 119, when the data for punching is stored in synchronization with the clock signal in the shift register 135, and then the latch signal is supplied to the data latch circuit 132, the data is stored in the shift register 135. Data latch circuit 13 corresponding to the
2 and stored.

At the same time, the data is stored in each driver 1
28. In this state, when a perforation pulse signal of logic “0” is applied from the perforation strobe input terminal 130 to the input terminal of the inverter 128, a signal of logic “1” is output from the output terminal of the inverter 128 and each driver 128 Is applied to the input terminal.

Therefore, when the data of the data latch circuit 132 is logic “1”, the output side of the driver 128 becomes logic “0”, and the drive current is supplied from the power supply terminal 127 to the corresponding heating element 103. . At this time, the pulse width of the drilling pulse signal input to the drilling strobe input terminal 130 is set so that the surface temperature of the heating element 103 becomes a temperature suitable for thermal drilling.

Next, a punching process for punching a character string pattern on the stamp face portion 33 of the stamp body 1 using the heating punching device 50 will be described with reference to the flowcharts of FIGS. The punching process includes a process executed by the control unit 110 and an operation executed by an operator.
3) indicate each step.

When the main switch 67 is turned on, the process is started. First, detection signals from the proximity switches 104 and 105 are read (S1), and then whether or not the stamp body 1 is present, that is, the stamp body 1 is pierced. It is determined whether or not it is mounted on the mounting unit 71 (S2), and the determination is Yes.
In other words, when the power is turned on while the stamp body 1 is still mounted on the perforation mounting section 71, a message "Please remove the stamp body" is displayed on a liquid crystal display (hereinafter referred to as LCD) 53. Is displayed (S3), S1
Return to Until the stamp body 1 is removed by the operator, S1 to S3 are repeatedly executed. Door 7
When the stamp body 1 is removed by opening the stamp member 5, it is determined as No in S2.

Next, when the power is turned on, the stamp body 1 is not mounted on the mounting portion 71 for perforation, or when the power is turned on, the stamp body 1 is mounted on the mounting portion 71 for perforation. When the stamp body 1 is removed and the determination in S2 is No, the data in the RAM 112 of the heating and punching device 50 is cleared. The carriage feed motor 100 is driven to move the carriage 87 into the guide lot 8.
8 Initial setting such as moving to the initial position at the right end is performed, and "under preparation" is displayed on the LCD 53 (S
4). Next, in step S5, the input setting of the stamp face contents is executed by operating the keyboard 52. In this input setting, the stamp face size designation, the format input including the setting of the character size and the character arrangement, and the punching The input of the character string data to the input buffer 124 is executed.

Next, a message "Please attach a stamp body" is displayed on the LCD 53 (S6), and the process stands by until the punching switch 66 is turned on (S7: No).
During this time, the operator opens the door 75, attaches the stamp body 1, and then closes the door, that is, the stamp body 1
Is mounted on the mounting portion 71 for drilling.

By opening the door 75, the sector gear 76 rotates clockwise in FIG. This sector gear 7
Along with the rotation of 6, the head switching rod 89 rotates in the counterclockwise direction in the figure via the gear 98 meshing with the sector gear 76. Then, the cam body 91 attached to the head switching rod 89 is turned to the horizontal position, and the thermal head 90 is released downward together with the head radiating plate 94.

The operator inserts the stamp body 1 through the opening 74 while engaging the guide groove 15 of the grip portion 2 of the stamp body 1 with the guide portion 80. During this insertion, the thermal head 90 does not hinder the mounting of the stamp body 1.
Further, with the insertion, the guide bar 83 is inserted through the guide holes 18, 44, 44 of the stamp body 1. As a result, the gate-shaped portion 43 rises along the tapered surface 84 of the guide bar 83, and as the gate-shaped portion 43 rises, as shown in FIG. Then, it rises so as to be positioned higher than that, and the state is maintained as shown in FIG.

The operator presses the stamp body 1 against the engaging portion 85 of the guide bar 83 and engages the right roller 81 provided on the guide member 78 with the engaging concave portion 16 of the grip portion 2 of the stamp body 83. Insert until done. When the stamp body 1 is inserted until it abuts and engages, the stamp body 1 is disposed at a predetermined position in the mounting portion 71 for boring shown in FIG.

Next, the operator performs a closing operation of rotating the door 75 in the counterclockwise direction in FIG. Along with this closing operation, the sector gear 76 rotates counterclockwise in FIG.
With the rotation of the sector gear 76, the head switching rod 89 rotates clockwise in FIG. Then, the cam body 91 attached to the head switching rod 89 is set in the upright posture,
The thermal head 90 includes the cam contact plate 93 and the spring 97
The stamp body 1 is disposed at a perforation position for pressing the right end of the stamp face portion 33 of the stamp body 1 shown by a solid line in FIG.

As described above, the operator operates the stamp body 1
After the is mounted, the perforation switch 66 is turned ON.

Next, when the perforation switch 66 is turned ON (S7: Yes), the detection signals of the proximity switches 104 and 105 are read (S8), and next, whether or not the stamp body 1 is present, that is, the stamp It is determined whether or not the body 1 is mounted on the mounting portion 71 for piercing (S9). When the determination is No, that is, when the operator operates the piercing switch 66 without mounting the stamp body 1, In S10, "Please attach a stamp body" is displayed on the LCD 53, and then the flow shifts to S7. On the other hand, the determination in S9 is Ye
In s, if the stamp body 1 is mounted, S11
, The stamp face size and stamp body 1 set in S5
It is determined whether or not the size is compatible. The size of the stamp body 1 means the proximity switches 104 and 105.
Is the width size of the stamp body 1 determined based on the detection signal from the stamp body 1.

Next, when the determination in S11 is No, that is,
If the size of the stamp body 1 does not conform to the set stamp face size, "Please replace the stamp body" is displayed on the LCD 53 (S12), and the process proceeds to S7. Steps S7 to S12 are repeatedly performed until the currently mounted stamp body 1 is removed and a stamp body 1 having a size matching the set stamp size is mounted.

On the other hand, when the judgment in S11 is Yes, ie,
When the size of the attached stamp body 1 matches the set stamp face size, a punching process is performed on the stamp face portion 33 of the stamp body 1 and during the punching process, the LCD 53 is used.
Displays "drilling" (S13). In the punching process, first, dot pattern data for punching is created based on the format and character string data input to the input buffer 124 and stored in the punching buffer 125.
The carriage feed motor 100 is driven based on the dot pattern data stored in the perforation buffer 125, the carriage 87 moves from the position indicated by the solid line in FIG. 21 to the position indicated by the two-dot chain line, and the thermal head 90 is driven. Then, a perforation based on the perforated dot pattern data is formed in the stamp face portion 33.

At the end of drilling, the thermal head 90
Until the carriage 8 is displaced leftward from the stamp face 33.
7 is driven to move, so that the thermal head 90 does not continue to press the stamp surface portion 33, thereby preventing the leakage of ink. Next, in S14, it is determined whether or not the perforation is completed. When the perforation is completed, in S15, "perforation processing completed" and "Please remove the stamp body" are displayed on the LCD 53,
The process returns to S1. The operator opens the opening / closing door 75 after seeing the display of “Please remove the stamp body”,
Remove the stamp body 1. At this time, since the carriage 87 has moved to the position shown by the two-dot chain line in FIG. 21, the carriage 87 and the thermal head 90 do not prevent the removal of the stamp body 1.

If the stamp body 1 is not removed, S1 to S3 of the above-described processing steps are repeated until the stamp body 1 is removed.

Next, the operation of the stamp body 1 and the heat punch 50 described above will be described.

Regarding the stamp body 1, a large number of perforations having a desired pattern are formed in advance on the heat-sensitive stencil sheet 28 forming the stamp face portion 33, the protective cap 7 is removed, and the stamp face portion 33 is inserted via the skirt member 6. After positioning at a desired position on the surface of the paper, grasping the gripping portion 2 and pushing the gripping portion 2 downward, and pressing the stamp surface portion 33 against the surface of the paper, the ink in the impregnating body 27 pierces a large number of holes. To permeate, the perforation pattern can be printed on the surface of the paper.

An up-and-down skirt member 6 surrounding the outer periphery of the stamp portion 3 is provided, and the skirt member 6 is attached to the first
The skirt member 6 is configured to be able to move up and down over a position, a second position, and a third position.
Since the elastic member is elastically biased toward the first position, a desired pattern can be perforated in the stamp face portion 33 in a dod pattern while the skirt member 6 is held at the third position.

In printing, the skirt member 6 is held at the first position, the skirt member 6 is set at a position on the surface of the paper to be printed, the stamp surface portion 33 is positioned, and When the is pressed, the spring 21 contracts and the skirt member 6 rises to the second position, so that printing can be performed accurately at a desired position. Then, after the printing, if the pressing force on the grip portion 2 is released, the return operation of the skirt member 6 to the first position promotes the peeling of the paper from the stamp face portion 33, so that the printing can be performed neatly on thin paper. can do. However, when printing is performed in a narrow frame on the surface of the sheet, printing can be performed with the skirt member 6 held at the second position or the third position by hand.

Further, when not in use, the skirt member 6 is held at the first position by the urging force of the spring 21, and the entire stamp body 1 is supported by the skirt member 6, thereby protecting the stamp face portion 33.

Further, a heat-sensitive stencil sheet 28 is provided on the stamp portion 3 to cover the surface of the impregnated body 27 in a fixed manner, and the heat-sensitive stencil sheet extending to the outer peripheral side of the base member 26 inside the skirt member 6. Since the outer peripheral holding member 5 surrounding the outer peripheral portion of the stencil paper 28 is provided, the outer peripheral portion of the heat-sensitive stencil paper 28 extending to the outer peripheral side of the base member 26 can be prevented from being damaged by the skirt member 6, and the impregnated body 27 can be prevented. Can be prevented from flowing out to the outside.

Further, since the protection cap 7 for covering the stamp face portion 33 of the stamp section 3 and being provided detachably on the stamp section 3 is provided, the protection cap 7 allows the stamp face section when not in use. 33 can be prevented from being damaged and dust can be attached, and printing can be prevented from being performed at a position where printing should not be performed due to an erroneous operation.

[0096] Regarding the heating and punching device 50, when the stamp body 1 is mounted on the mounting portion 71 for punching, the stamp body 1
It is supported by a pair of front and rear guide portions engaged with the pair of front and rear guide grooves 15, and is pressed backward by a pair of rollers 81 to accurately set the position of the stamp body 1 in the front and rear direction.

The stamp body 1 is locked by the locking portion 85 and locked by the ends of the pair of front and rear guide grooves 15, so that the position in the left-right direction is accurately set. Moreover,
Since one roller 81 is engaged with the engaging recess 16 of the stamp body 1, the position of the stamp body 1 does not shift during punching.

The opening / closing door 75 and the cam body 91 are interlocked via the sector gear 76 and gear 98 and the head switching rod 89, and the stamp body 1 is mounted on the perforated mounting portion 71 until the door 75 is closed. Since the thermal head 90 is configured to be released downward, the stamp face 1 is not damaged when the stamp body 1 is mounted, and the thermal head 90 is not damaged after the perforation is completed. The carriage 87 is moved until it retreats leftward from the stamp surface 33.
Is moved, the thermal head 90 does not continue to press the stamp surface portion 33, so that leakage of ink from the stamp surface portion 33 can be prevented. When removing the stamp body 1 after the perforation, the opening and closing door 75 opens the thermal head 9.
Since 0 is released downward, the stamp face 33 is not damaged even when the stamp body 1 is taken out.

When the stamp body 1 is mounted on the mounting portion 71 for perforation, the skirt member 6 is switched to the third highest position by the guide bar 83. , Does not interfere with perforation.

Since the width size of the stamp body 1 is detected by the proximity switches 104 and 105, the size of the stamp body 1 is not mistaken and a character string that does not conform to the size of the stamp face portion 33 is not pierced. . Further, the stamp body 1 is provided with a guide member 78 in the mounting portion 71 for punching.
Since the gripping portion 2 has the same configuration, both the narrow stamp body 1 and the wide stamp body 1 can be mounted on the mounting portion 71 for drilling. Therefore, it is excellent in versatility.

The presence / absence of the stamp body 1 is detected by the proximity switches 104 and 105, and control is performed so that the next operation is not performed unless the stamp body 1 is removed when the power is turned on or after the punching is completed. Therefore, it is possible to prevent the punch body 1 from being forgotten to be removed,
There is no double perforation.

In the above embodiment, the keyboard 52
Corresponds to the input means, the heating perforation mechanism 72 corresponds to the perforation means, the control unit 110 corresponds to the drive control means and the separation control means, and the RAM 113 corresponds to the data storage means.

Here, a part of the above embodiment can be modified as follows.

1] The mounting portion 71 for perforation is
Is mounted detachably from the right, but the stamp body 1 may be mounted detachably from above. In this case, the stamp body 1 is further attached to the mounting portion 71 for boring.
It is also possible to provide a mechanism for lifting up more, and to control the thermal head 90 and the stamp surface portion 33 of the stamp body 1 up and down by driving the lift-up mechanism immediately upon completion of the punching operation.

2) The heating perforating mechanism 72 is configured to perforate while moving the thermal head 90 via the carriage 87 while holding the stamp body 1 at a predetermined position. Alternatively, the stamp body 1 may be configured to be perforated while moving. In this case, the stamp body 1 may be continuously moved even at the end of the punching operation, and the thermal head 90 may be controlled to be displaced to a position away from the stamp surface portion 33 of the stamp body 1.

3) A solenoid actuator may be provided in place of the cam body 91, and the position of the thermal head 90 may be switched by the actuator. In this case, the actuator may be switched immediately at the end of the punching operation so that the thermal head 90 does not press the stamp face portion 33 of the stamp body 1 so as to be in a rest state as shown in FIG.

4) The rack 92, drive gear 101,
Instead of the reduction gear mechanism 107, the carriage 87 may be driven to move in the left-right direction via a wire and a pulley.

5) Instead of the impregnated body 27, an ink body composed of a mass of ink having a high viscosity is used. This ink body is mounted in the concave portion 25, and is raised to the same shape as the impregnated body 27. Is also good.

6) In the processing step S3 or S15, instead of displaying a message for prompting the removal of the stamp body 1 on the LCD 53, a buzzer or a vocalization device or the like is provided, and the removal of the stamp body 1 is prompted by a sound generated by these. It may be.

[0110]

As is apparent from the above description, the heating and punching apparatus for a stamp body according to the first aspect of the present invention quickly moves the thermal head and the stamp face of the stamp body after the completion of the punching operation. Control is performed so as to take the separated position. Therefore, it is possible to prevent the thermal head from continuously pressing the stamp surface portion, and to prevent ink contamination in the heating and punching apparatus, such as adhesion of ink to the thermal head.

Further, in the heating and punching apparatus for a stamp body according to the second aspect of the present invention, after the punching operation is completed, the thermal head is driven to move to a position where the thermal head is separated from the stamp face, so that the thermal head presses the stamp face. It is possible to prevent the ink from leaking continuously.

[Brief description of the drawings]

FIG. 1 is a perspective view of a stamp body mounted on a stamp body heating perforation apparatus according to one embodiment of the present invention.

FIG. 2 is an exploded perspective view of a stamp body.

FIG. 3 is a vertical sectional front view of a stamp body.

FIG. 4 is a vertical sectional side view of a stamp body.

FIG. 5 is an enlarged vertical sectional front view of a stamp body of the stamp body.

FIG. 6 is an enlarged sectional view of a heat-sensitive stencil sheet of a stamp body.

FIG. 7 is a perspective view illustrating a method for manufacturing a stamp portion main body.

FIG. 8 is a vertical sectional front view of the stamp body when the skirt member is at a third position.

FIG. 9 is a vertical sectional front view of the stamp body when the skirt member is at the second position.

FIG. 10 is a diagram showing an example of a pattern for perforating a stamp face of a stamp body.

FIG. 11 is a perspective view of a heating perforation apparatus according to an embodiment of the present invention.

FIG. 12 is a perspective view of a heat punch and a stamp body.

FIG. 13 is a plan view of the heating perforation apparatus.

FIG. 14 is a partially cutaway front view of the heating perforation apparatus.

FIG. 15 is a partially cut-away longitudinal side view of the heating perforation apparatus.

FIG. 16 is a perspective view of a heating perforation section of the heating perforation apparatus.

FIG. 17 is a perspective view of a main part of a heating perforation section of the heating perforation apparatus.

FIG. 18 is an exploded perspective view of the heating perforation mechanism.

FIG. 19 is a side view of a main part of a heating perforation section of the heating perforation apparatus.

FIG. 20 is a vertical sectional front view of a stamp body and a heated perforated portion being mounted on the perforated mounting portion.

FIG. 21 is a longitudinal sectional front view of the stamp body and the heated perforated portion after being mounted on the perforated mounting portion.

FIG. 22 is a block diagram of a control system of the stamp device.

FIG. 23 is an electric circuit diagram of a head drive circuit.

FIG. 24 is a part of a flowchart of a punching process performed by the heating punching apparatus.

FIG. 25 is the remaining part of the flowchart of the punching process performed by the heating punching device.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 stamp body 27 impregnated body 28 heat-sensitive stencil sheet 33 stamp face 50 heating perforating device 52 keyboard 71 perforating mounting section 72 heating perforating mechanism 87 carriage 88 guide rod 90 thermal head 91 cam body 100 stepping motor 110 control unit 111 CPU 112 ROM 113 RAM 114 CG-ROM for drilling

Claims (2)

[Claims] 1. A perforated mounting portion for detachably mounting a stamp body containing ink and having a stamp surface portion made of a heat-sensitive stencil sheet, and a stamp body mounted on the perforated mounting portion. A thermal head for punching the stamped surface portion in a dot shape, and a separation means for immediately separating the thermal head and the stamped surface portion when the operation of perforating the stamped surface portion by the thermal head is completed. A heat punching device for a stamp body, comprising: 2. A punching operation from one end to the other end of the stamp surface of the stamp body while moving the thermal head parallel to the longitudinal direction of the stamp surface of the stamp body attached to the mounting unit for punching. And a driving unit for moving the thermal head in the other end direction to a position away from the stamp surface after the perforation operation is completed.
4. The heating perforation device for a stamp body according to claim 1.