JP2016034653A - Laser marking device, print data generation device, print data generation method, and computer program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a laser marking device, a print data generation device, a print data generation method, and a computer program capable of printing a desired character or the like on the surface of a workpiece without the need to pay attention to a font data difference and the like.SOLUTION: A laser marking device comprises: a laser beam generation unit generating a laser beam; a laser beam scan unit scanning a surface of a mounted workpiece two-dimensionally by the laser beam; a laser beam control unit implementing laser printing on the basis of print data for printing a character string on the workpiece; and a print data generation unit generating the print data. The print data generation unit receives setting of information related to character strings including a predetermined character string to be printed on the workpiece, and receives selection of font data to be used for printing from among a plurality of stored font data. The print data generation unit extracts font data corresponding to the font data for which the selection is received, generates print data including the extracted font data and the predetermined character string for which the setting is received, and transmits the print data to the laser beam control unit.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a laser marking device, a print data generation device, a print data generation method, and a computer program that print characters or the like on the surface of a workpiece.

  The laser marking device includes a laser marker having a head and a controller, and a print data generation device that generates print data in accordance with a user instruction. The print data generated by the print data generation device includes information such as the contents of the character string to be printed, the print position, and the print size.

  In the laser marker and the print data generation device, font data relating to the font of characters is stored in advance, and only the print data is transmitted from the print data generation device to the laser marker. The laser marker controller generates development data based on the received print data and font data stored in advance.

  For example, in Patent Document 1, the development data is composed of line segment data that defines a trajectory to be followed by laser light, and laser control data for laser on / off control. The laser marker executes desired laser printing based on the development data.

JP 2004-243328 A

  When the font data stored in the laser marker is the same as the font data stored in the print data generation device, the character string to be laser-printed is the same. However, if both font data differ due to version differences, the difference in font data will be found when laser printing is performed on the workpiece, and the occurrence of resetting operations cannot be avoided beforehand. There was a problem.

  The present invention has been made in view of such circumstances, and a laser marking device and a print data generation device capable of printing a desired character or the like on the surface of a work without paying attention to differences in font data. An object of the present invention is to provide a print data generation method and a computer program.

  In order to achieve the above object, a laser marking device according to a first aspect of the present invention includes a laser light generation unit that emits laser light, a laser light scanning unit that scans a surface of a workpiece placed in a two-dimensional manner with laser light, A laser marking apparatus comprising: a laser beam control unit that performs laser printing based on print data for printing a character string on the workpiece; and a print data generation unit that generates print data, wherein the print data generation unit Is stored in a character string setting receiving means for receiving information related to a character string including a predetermined character string to be printed on the workpiece, and a font data storage means for storing a plurality of font data corresponding to a plurality of different fonts. Font selection acceptance means for accepting selection of font data to be printed from a plurality of font data, and accepting the selection Print data generation means for extracting font data corresponding to the font data and generating print data including the extracted font data and the predetermined character string for which the setting has been received, and the generated print data as the laser light control unit Print data transmission means for transmitting to the printer.

  Further, in the laser marking device according to the second invention, in the first invention, the print data generating means generates a single print data including the extracted font data and information on a predetermined character string. And

  In the laser marking device according to a third aspect of the present invention, in the first or second aspect, the print data generation unit corresponds to a character included in the predetermined character string whose setting is received by the character string setting reception unit. Only font data is extracted.

  The laser marking device according to a fourth aspect of the present invention is the first or second aspect of the invention, further comprising a group designation accepting unit that classifies and stores font data into a plurality of groups and accepts designation of the group by the user, The print data generating means extracts only font data belonging to the group whose designation is accepted by the group designation accepting means.

  The laser marking device according to a fifth aspect of the present invention includes, in the first or second aspect of the invention, an analysis unit that analyzes the predetermined character string whose setting has been received, and the print data generation unit is analyzed by the analysis unit. Based on the result, only font data corresponding to the usable character is extracted.

  The laser marking device according to a sixth aspect of the invention is the language designation according to the first or second aspect, wherein the font data is classified into a plurality of groups and stored for each language to be used, and the language designation by the user is accepted. The print data generation unit includes a reception unit, and extracts only font data belonging to a group corresponding to the language for which the specification is received by the language designation reception unit.

  According to a seventh aspect of the present invention, in the first or second aspect of the invention, the predetermined character string in which the font data is classified into a plurality of groups and stored for each language to be used, and the setting is accepted. Language extraction means for extracting and specifying the language used in the printing, wherein the print data generation means extracts only font data belonging to a group corresponding to the language extracted and specified by the language extraction means It is characterized by.

  The laser marking device according to an eighth aspect of the present invention is the laser marking device according to the first or second aspect, wherein the print data generating means is an alphanumeric character when the predetermined character string for which the setting has been received is composed of only alphanumeric characters. Only the corresponding font data is extracted.

  The laser marking device according to a ninth aspect of the present invention is the first or second aspect of the invention, further comprising a font designation accepting unit that accepts designation of font data by a user, wherein the print data generating unit only receives the font data for which designation has been accepted. It is characterized by extracting.

  The laser marking device according to a tenth aspect of the present invention is the laser marking device according to any one of the first to ninth aspects, wherein the laser light control unit includes means for storing the print data transmitted by the print data transmission means, When a communication command instructing to change a character string is input from the outside, the character string printed on the workpiece can be changed based on the input communication command and the font data included in the print data. Features.

  Next, in order to achieve the above object, a print data generating apparatus according to an eleventh aspect of the present invention includes a laser beam generator that emits laser beam, and a laser beam that scans the surface of the placed work in two dimensions with the laser beam. A print data generation device that is connected to the scanning unit and a laser beam control unit that performs laser printing based on print data for printing a character string on the workpiece so as to generate data. A character string setting accepting unit for accepting setting of information relating to a character string including a predetermined character string to be printed on the workpiece; a font data storing unit for storing a plurality of font data corresponding to a plurality of different fonts; A font selection receiving means for receiving a selection of font data to be printed from a plurality of font data, and a font data for which the selection has been received. Print data generating means for extracting the font data corresponding to the data and generating print data including the extracted font data and the predetermined character string for which the setting has been received, and the generated print data as the laser light control unit Print data transmission means for transmitting to the printer.

  Next, in order to achieve the above object, a print data generation method according to a twelfth aspect of the present invention includes a laser beam generator that emits laser beam and a laser beam that scans the surface of the placed workpiece two-dimensionally with the laser beam. In a print data generation device that is connected to a scanning unit and a laser beam control unit that performs laser printing based on print data for printing a character string on the workpiece, and that generates print data. A print data generation method that can be executed, wherein the print data generation device corresponds to a step of accepting setting of information relating to a character string including a predetermined character string to be printed on the work, and a plurality of different fonts. A step of storing a plurality of font data, a step of receiving selection of font data to be printed from the plurality of stored font data, Extracting font data corresponding to the received font data, generating print data including the extracted font data and the predetermined character string for which the setting has been received, and controlling the generated print data to the laser light And a step of transmitting to the part.

  Next, in order to achieve the above object, a computer program according to the thirteenth aspect of the present invention includes a laser light generating unit that emits laser light, and a laser light scanning unit that scans the surface of the placed workpiece two-dimensionally with laser light. And a print data generation device that generates print data and is connected to a laser beam control unit that performs laser printing based on print data for printing a character string on the workpiece. A character string setting accepting unit for accepting setting of information relating to a character string including a predetermined character string to be printed on the work; a plurality of corresponding to a plurality of different fonts Font data storage means for storing a plurality of font data, font data to be printed from a plurality of stored font data A font selection receiving means for receiving a selection of data, extracting font data corresponding to the font data for which the selection has been received, and generating print data including the extracted font data and the predetermined character string for which the setting has been received And a print data transmission unit for transmitting the generated print data to the laser light control unit.

  In the first invention, the eleventh invention, the twelfth invention and the thirteenth invention, setting of information relating to a character string including a predetermined character string to be printed on a work is accepted, and a print target is selected from a plurality of stored font data. Accepts selection of font data. Font data corresponding to the selected font data is extracted, and print data including the extracted font data and a predetermined character string whose setting is received is generated. This makes it possible to generate print data containing only the font data necessary for printing without storing all font data in the laser light control unit, so the fonts can be unified even when printing on different devices. Since it is not necessary to transmit all font data with a large capacity together with the print data, the communication load can be reduced and the laser light control unit does not require a large storage capacity. .

  In the second invention, by generating a single print data including the extracted font data and information on a predetermined character string, the fonts can be unified and printed even when printing with different devices. In addition, since it is not necessary to transmit all the font data having a large capacity together with the print data, the communication load can be reduced and the laser light control unit does not require a large storage capacity.

  In the third invention, by extracting only the font data corresponding to the characters included in the predetermined character string for which the setting has been accepted, the fonts can be unified and printed even when printing with different devices. Since it is sufficient to transmit only font data necessary for printing, the communication load can be reduced and a large storage capacity is not required for the laser light control unit.

  In the fourth invention, the font data is classified into a plurality of groups and stored, the designation of the group by the user is accepted, and only the font data belonging to the group for which the designation is accepted is extracted for printing on a different device Even so, it is possible to print the fonts in a unified manner, and it is sufficient to transmit only the font data belonging to the group that has received the designation, so that the communication load can be reduced and a large memory is stored in the laser light control unit. Does not require capacity.

  According to the fifth aspect of the invention, a predetermined character string that has received a setting is analyzed, and based on the analyzed result, only font data corresponding to a usable character is extracted, and printing is performed with a different device. Even if there is, it is possible to print the fonts in a unified manner, and it is sufficient to send only the font data determined to be necessary for printing by analysis, so the communication load can be reduced and the laser light control unit Does not require storage capacity. For example, in the case of counter printing displayed in hexadecimal, only the font data of numbers “0” to “9” and the font data of English characters “A” to “F” are sufficient.

  In the sixth invention, for each language to be used, font data is classified into a plurality of groups and stored, the language designation by the user is accepted, and only the font data belonging to the group corresponding to the designated language is extracted. By doing this, even when printing on different devices, the fonts can be unified and printed, and only the font data of the group corresponding to the language for which the designation is accepted needs to be transmitted, thus reducing the communication load. In addition, the laser light control unit does not require a large storage capacity.

  In the seventh invention, for each language to be used, font data is classified and stored in a plurality of groups, and the language used in the predetermined character string for which the setting has been received is extracted, specified, extracted. By extracting only the font data belonging to the group corresponding to the specified language, it is possible to unify and print the font even when printing on different devices, and also supports the extracted and specified language Since it is sufficient to transmit only font data belonging to the group to be transmitted, the communication load can be reduced, and the laser light control unit does not require a large storage capacity.

  In the eighth invention, when the predetermined character string for which the setting has been received is composed of only alphanumeric characters, the font can be selected even when printing on a different device by extracting only the font data corresponding to the alphanumeric characters. In addition to being able to print uniformly, it is sufficient to transmit only font data corresponding to alphanumeric characters, so that the communication load can be reduced and the laser light control unit does not require a large storage capacity.

  In the ninth invention, by accepting the specification of the font data by the user and extracting only the font data for which the designation has been accepted, the font can be unified and printed even when printing on different devices. Therefore, it is sufficient to transmit only the font data that has been accepted, so that the communication load can be reduced and the laser light control unit does not require a large storage capacity.

  In the tenth invention, when the transmitted print data is stored and a communication command for instructing the change of the character string is input from the outside, the work is performed based on the input communication command and the font data included in the print data. Since the character string to be printed can be changed, it is possible to refer to the font data stored in the laser light control unit and send it through the PC application simply by sending a communication command for changing the character string to the controller of the laser marking device. The character string can be changed with a desired font without any change.

  According to the present invention, print data including only font data necessary for printing can be generated without storing all font data in the laser light control unit. The fonts can be printed in a unified manner, and it is not necessary to send all the font data with a large capacity together with the print data, so the communication load can be reduced and the laser light control unit has a large storage capacity. do not need.

It is a block diagram showing typically the composition of the laser marking device concerning an embodiment of the invention. It is a block diagram which shows the structure in the case of using the solid state laser marker of the laser marking apparatus which concerns on embodiment of this invention. It is a block diagram which shows the structure in the case of using the fiber laser marker of the laser marking apparatus which concerns on embodiment of this invention. It is a block diagram which shows the structure at the time of using control parts, such as CPU, of the printing data generation apparatus which concerns on embodiment of this invention. It is a functional block diagram of a print data generation device according to an embodiment of the present invention. It is an illustration figure of the printing data setting screen of the printing data generation apparatus which concerns on embodiment of this invention. It is an illustration figure of the font selection reception screen of the printing data generation apparatus which concerns on embodiment of this invention. It is an illustration figure of the font data contained in the printing data of the printing data generation apparatus which concerns on embodiment of this invention. It is a flowchart which shows the procedure of the print data generation process of CPU of the print data generation apparatus which concerns on embodiment of this invention.

  Hereinafter, a laser marking device according to an embodiment of the present invention will be specifically described with reference to the drawings. FIG. 1 is a block diagram schematically showing a configuration of a laser marking device according to an embodiment of the present invention.

  As shown in FIG. 1, a laser marking device 10 according to the present embodiment includes a marking head (laser beam scanning unit) 1 and a controller (laser beam generation unit and laser beam control unit) that controls the operation of the marking head 1. 2 and a print data generation device (print data generation unit) 3 connected so as to be able to perform data communication with the controller 2. The print data generation device 3 transmits print data to the controller 2. The print data generation device 3 is preferably composed of a computer installed with a program for generating print data, a programmable logic controller (PLC), and the like.

  Various external devices 4 are connected to the controller 2 as necessary. Examples of the external device 4 include an image recognition device 401 such as an image sensor for confirming the type and position of the workpiece W conveyed on the line, a displacement meter for acquiring information on the distance between the workpiece W and the marking head 1, and the like. The distance measuring device 402, the PLC 403 that controls the device according to a predetermined sequence, the PD sensor that detects the passage of the workpiece W, various other sensors, and the like can be exemplified.

  The laser marking device 10 sets a print pattern to be printed on the surface of the workpiece W and prints on the surface of the workpiece W. FIG. 2 is a block diagram showing a configuration of the laser marking device 10 according to the embodiment of the present invention when a solid-state laser marker is used. Note that printing means marking of characters, symbols, figures, etc., specifically hiragana, katakana, kanji, alphabet, numbers, symbols, pictograms, icons, logos, barcodes, two-dimensional codes, etc. Includes graphics.

  The laser marking device 10 includes a controller 2 (including a laser light generation unit 200 and a laser light control unit 201) and a marking head 1 (laser output unit 202), and a laser of a laser oscillation unit 204 included in the laser output unit 202. The laser beam Lb oscillated by the medium 206 is scanned on the surface of the work W in a two-dimensional manner to print on the surface of the work W. The print signal for controlling the print operation is an on / off signal of the laser beam Lb, and is a PWM signal corresponding to one pulse of the laser beam Lb from which one pulse is oscillated. The PWM signal can define the laser intensity based on a duty ratio corresponding to the frequency. As a modification, the laser intensity may be defined by the scanning speed based on the frequency.

  The laser light generation unit 200 includes a laser excitation light source 208 and a condensing unit 210, and a constant pressure power source is supplied from the power source to the laser excitation light source 208. The laser excitation light source 208 is constituted by a semiconductor laser, a lamp, or the like. Specifically, the laser excitation light source 208 is configured by a laser diode array in which a plurality of semiconductor laser diode elements are arranged in a straight line, and laser oscillation from each element is output in a line shape. Is incident on.

The laser beam generator 200 and the laser output unit 202 are connected by an optical fiber cable 212, and the laser excitation light generated by the laser beam generator 200 is incident on the laser medium 206 described above. The laser medium 206 is composed of a rod-shaped solid laser medium (for example, Nd: YVO ₄ ), is excited by inputting laser excitation light from one end face, and emits a laser beam Lb from the other end face, so-called end pumping. The excitation method by is adopted. The laser medium 206 may be configured such that the wavelength of the laser beam Lb to be output can be converted to an arbitrary wavelength by combining a solid-state laser medium with a wavelength conversion element.

  The laser medium 206 may be formed of a wavelength conversion element that performs only wavelength conversion without using a resonator that oscillates a laser beam, instead of the solid-state laser medium described above. In this case, wavelength conversion may be performed on the output light of the semiconductor laser.

Examples of the wavelength conversion element include KTP (KTiPO ₄ ), organic nonlinear optical materials and other inorganic nonlinear optical materials such as KN (KNbO ₃ ), KAP (KAsPO ₄ ), BBO, LBO, and bulk type polarization inversion elements ( LiNbO ₃ (Periodically Polled Lithium Niobate: PPLN), LiTaO ₃ or the like) can be used. Further, a semiconductor laser for an excitation light source of a laser by up-conversion using a fluoride fiber doped with rare earth such as Ho, Er, Tm, Sm, and Nd can be used.

  The laser output unit 202 includes the above-described laser oscillation unit 204 that generates the laser beam Lb. The laser oscillation unit 204 includes an output mirror and a total reflection mirror that face each other at a predetermined distance along the optical path of the stimulated emission light emitted from the laser medium 206 described above, an aperture disposed between them, and a Q A switch is provided. The stimulated emission light emitted from the laser medium 206 is amplified by multiple reflection between the output mirror and the total reflection mirror, and the mode is selected by the aperture while being cut off in a short period by the operation of the Q switch, and the output mirror is Then, the laser beam Lb is output.

As the laser oscillation unit 204, a gas laser system using a gas such as CO ₂ , helium-neon, argon, or nitrogen as a medium may be employed. For example, when a carbon dioxide laser is used, the laser oscillation unit 204 is filled with carbon dioxide (CO ₂ ) inside the laser oscillation unit 204 including the built-in electrode, and the carbon dioxide gas is produced by the built-in electrode based on a print signal given from the controller 2. Is excited to cause laser oscillation.

  The laser beam scanning system 220 includes a beam expander 242 that incorporates a Z-axis scanner whose optical path coincides with the laser oscillation unit 204, an X-axis scanner 224, and a Y-axis scanner 226 that is arranged to be orthogonal to the X-axis scanner 224. With. The laser beam scanning system 220 causes the X-axis scanner 224 and the Y-axis scanner 226 to scan the laser beam Lb emitted from the laser oscillation unit 204 two-dimensionally in the work area on the surface of the workpiece W.

  The X-axis scanner 224 and the Y-axis scanner 226 are galvano motors 224b for rotating with galvano mirrors 224a, 226a, galvano mirrors 224a, 226a, which are total reflection mirrors, as reflecting surfaces that reflect light. 226b, and a position detection unit that detects the rotation position of the rotation shaft and outputs it as a position signal. The X-axis scanner 224 and the Y-axis scanner 226 are connected to the scanner drive circuit 228. The scanner driving circuit 228 is connected to the controller 2 and drives the X-axis scanner 224 and the Y-axis scanner 226 based on a control signal supplied from the controller 2.

  The beam expander 242 adjusts the spot diameter of the laser beam Lb emitted from the laser medium 206. By adjusting the spot diameter, the working distance (focal length) can be adjusted. That is, by changing the relative distance between the entrance lens and the exit lens by the beam expander 242, the beam diameter of the laser beam Lb can be enlarged / reduced, and the focal position can be changed.

  By controlling the operations of the beam expander 242, the X-axis scanner 224, and the Y-axis scanner 226, the laser beam Lb can be scanned while adjusting the working distance. Therefore, it is possible to print with high accuracy and the minimum spot in a state where the focal length is adjusted with respect to the surface of the workpiece W.

  FIG. 3 is a block diagram showing the configuration of the laser marking device 10 according to the embodiment of the present invention when a fiber laser marker is used. As shown in FIG. 3, the laser marking device 10 includes a controller 2 and a marking head 1, and a print data generation device 3 connected to the controller 2 receives an input of a print condition or the like of the workpiece W, and displays The input / output means includes a display unit for displaying a parameter setting screen corresponding to the printing condition.

  The controller 2 includes a laser oscillator unit including a main control circuit 508, a workpiece machining information storage unit 510, a power supply circuit 512, an excitation light source 514, and a laser beam amplifier 516. The controller 2 controls laser oscillation and laser beam scanning. Etc. are executed. The excitation light source 514 includes a light emitting element such as an LD (laser diode) that generates excitation light for exciting the laser medium, and a condenser lens.

  The laser beam amplifier 516 includes an optical fiber in which a laser medium is added to the core. By amplifying the laser beam using the laser beam amplifier 516, a high-power laser beam with high energy density can be generated. The laser beam amplifier 516 includes a master oscillator unit that generates low-output seed light, a power amplifier unit that amplifies the seed light, a pumping light source device, an isolator, and the like. The master oscillator unit and the power amplifier unit serve as a laser medium. It is composed of a rare earth-doped optical fiber to which a rare earth element such as ytterbium (Yb) is added.

  The controller 2 and the marking head 1 are connected by an optical fiber cable 520, and the laser beam amplified by the laser beam amplifier 516 is directly input to the optical fiber cable 520.

  The marking head 1 includes an optical isolator 522, a beam expander 524, a beam sampler 526, a shutter 528, a photo interrupter 530, a dichroic mirror 532, a Z axis scanner 534, an X axis / Y axis scanner 536, a power monitor 538, and a guide light source 540. Including.

  The optical isolator 522 constitutes return light suppression means that transmits the laser beam emitted from the end face of the optical fiber cable 520 and suppresses the return light. The optical isolator 522 transmits the laser beam transmitted via the optical fiber cable 520 to the beam expander. Transmission in the forward direction input to 524 is allowed, and transmission in the reverse direction is prohibited. The optical isolator 522 includes, for example, an aperture, a polarizer, and a Faraday rotator. The aperture is a blocking plate for limiting the passing light. The polarizer is a rod-shaped optical element made of a birefringent crystal. A Faraday rotator is a magneto-optical element that rotates a plane of polarization by applying a magnetic field.

  The beam expander 524 constitutes a beam diameter varying unit that variably controls the beam diameter of the laser beam, and is arranged with the optical axis of the optical isolator 522 aligned. The beam expander 524 includes a plurality of lenses arranged on the optical path, and converts the beam diameter to a desired value by adjusting the distance between the lenses. The beam sampler 526 is an optical element that reflects part of the laser beam that has passed through the beam expander 524 toward the dichroic mirror 532 and transmits the other part to the power monitor 538 side.

  The power monitor 538 is a laser power detection sensor that receives the laser beam that has passed through the beam sampler 526 and detects the laser power. The power monitor 538 uses the detection result of the laser power as a power level detection signal to the main control circuit 508 in the controller 2. Output. As the power monitor 538, for example, a thermopile (thermoelectric stack), a photodiode, or the like is used.

  The shutter 528 is a blocking device for blocking the laser beam as necessary, and includes a blocking plate and a drive mechanism that moves the blocking plate. The shutter 528 is disposed between the beam sampler 526 and the dichroic mirror 532.

  The photo interrupter 530 is an optical sensor that optically detects whether or not the shutter 528 is closed. The dichroic mirror 532 is an optical element that reflects only light of a specific wavelength and transmits light of other wavelengths. The dichroic mirror 532 reflects the laser beam that has passed through the shutter 528 toward the Z-axis scanner 534 and emits light from the guide light source 540. The guide light is transmitted as it is.

  The Z-axis scanner 534 is a laser beam scanning mechanism including one or two or more lenses arranged on an optical path and a lens driving motor for moving the lens. By displacing the lens, the marking head 1 The focal position of the laser beam emitted from can be adjusted in the optical axis direction. The Z-axis scanner 534 has a laser beam condensing function. The Z-axis scanner 534 is a scanning mechanism that can move the focal position of the laser beam in the optical axis direction following the height of the workpiece W.

  The X-axis / Y-axis scanner 536 is a laser beam scanning mechanism composed of two galvanometer mirrors arranged on intersecting rotation axes and a galvanometer mirror driving motor for rotating the galvanometer mirror. By rotating the axis, the laser beam is scanned in a direction intersecting the optical axis. Here, the optical axis direction of the laser beam applied to the print target surface is referred to as a Z-axis direction, and two non-parallel directions intersecting the optical axis are referred to as an X-axis direction and a Y-axis direction, respectively.

  The laser beam that has passed through the Z-axis scanner 534 is reflected by the galvanometer mirror of the X-axis / Y-axis scanner 536 and applied to the workpiece W. The guide light source 540 is a light source device that generates guide light for visualizing the irradiation position of the laser beam Lb on the workpiece W. Guide light emitted from the guide light source 540 passes through the dichroic mirror 532 and enters the optical path of the laser beam. The guide light that has entered the optical path of the laser beam is applied to the workpiece W via the Z-axis scanner 534 and the X-axis / Y-axis scanner 536.

  The workpiece machining information storage unit 510 of the controller 2 is a memory that holds information related to laser printing of the workpiece W as workpiece machining information. As workpiece machining information, machining line drawing information when a character or the like is machined on the workpiece W. Laser output control information for controlling laser oscillation is held.

  The main control circuit 508 includes an excitation light source 514, a laser beam amplifier 516, a Z-axis scanner 534, an X-axis / Y-axis scanner 536, and a shutter 528 based on the workpiece machining information held in the workpiece machining information storage unit 510. A control means for controlling, specifically, generating an oscillator control signal for adjusting the peak power and pulse width of the laser beam emitted from the marking head 1 on the basis of the laser output control information; Control signals are output to 514 and the laser beam amplifier 516.

  The main control circuit 508 controls the lens driving motor of the Z-axis scanner 534, the mirror driving motor of the X-axis / Y-axis scanner 536, and the shutter 528 based on the laser output control information and the drawing information. , And various control signals are output to the Z-axis scanner 534, the X-axis / Y-axis scanner 536, and the shutter 528.

  FIG. 4 is a block diagram showing the configuration of the print data generation device (print data generation unit) 3 according to the embodiment of the present invention when a control unit such as a CPU is used. As shown in FIG. 4, the print data generation device 3 according to the present embodiment includes a CPU (control unit) 31 that executes at least a control program that controls operations, a memory 32, a storage device 33, an I / O interface 34, A video interface 35, a portable disk drive 36, a communication interface 37, and an internal bus 38 are provided.

  The CPU 31 is connected to the above-described hardware units of the print data generation device 3 via the internal bus 38, and controls the operation of the above-described hardware units and stores the computer program stored in the storage device 33. According to 100, various software functions are performed. The memory 32 is composed of a volatile memory such as SRAM or SDRAM, and a load module is expanded when the computer program 100 is executed, and stores temporary data generated when the computer program 100 is executed.

  The storage device 33 includes a built-in fixed storage device (hard disk), a ROM, and the like. The computer program 100 stored in the storage device 33 is downloaded by a portable disk drive 36 from a portable recording medium 90 such as a DVD or CD-ROM in which information such as programs and data is recorded, and from the storage device 33 at the time of execution. It is expanded into the memory 32 and executed. Of course, a computer program downloaded from an external computer connected via the communication interface 37 may be used.

  The storage device 33 includes a font data storage unit 331. The font data storage unit 331 stores a plurality of font data respectively corresponding to a plurality of different types of fonts. Further, even for the same type of font data, font data such as kana characters, katakana characters, numbers, and English characters are classified and stored according to the character type.

  The communication interface 37 is connected to the internal bus 38 and can perform data communication by being connected to the controller 2 via a connection line. Specifically, part of the print data and font data is transmitted to the controller 2. Of course, it may be connected to an external computer via the Internet or the like, and for example, a computer program or the like may be downloaded.

  The I / O interface 34 is connected to input devices such as a keyboard 41 and a mouse 42 and receives input of data to be printed on the surface of the work W (print data). The video interface 35 is connected to a display device 43 such as an LCD, and displays a screen for accepting data input, a state of a character string printed on the surface of the work W, and the like.

  FIG. 5 is a functional block diagram of the print data generation device (print data generation unit) 3 according to the embodiment of the present invention. The character string setting accepting unit 301 of the print data generating device 3 of the laser marking device 10 according to the present embodiment accepts setting of information related to a predetermined character string to be printed on the workpiece W.

  FIG. 6 is a view showing an example of a print data setting screen of the print data generating device 3 according to the embodiment of the present invention. 6A is an exemplary diagram of a screen for setting a character string as print data, FIG. 6B is an exemplary diagram of a layout setting screen for print data, and FIG. 6C is a print data print condition. The example figure of a setting screen is shown, respectively.

  In FIG. 6A, the character string setting area 61 accepts the setting of the character string to be printed. Then, the font setting area 62 accepts the setting of the font data of the character string to be printed, and the size setting area 63 accepts the setting of the size of the character string to be printed. In the example of FIG. 6, the setting is accepted so that the character string “Osaka” is printed in the font “Mincho” with a character height of 10 mm, a character width of 3 mm, and a character spacing of 1.886 mm.

  In FIG. 6B, the setting of the shape of the printing surface is accepted in the printing surface setting area 64. The coordinate setting area 65 accepts the setting of the coordinates of the character string to be printed, and the angle setting area 66 accepts the setting of the angle of the character string to be printed. In the example of FIG. 6, printing is performed on the XY plane, and the setting of the center coordinates of the character string is accepted.

  In FIG. 6C, the printing condition setting area 67 accepts the printing condition setting. In the fill setting area 68, settings such as a fill pattern are accepted. In the example of FIG. 6, settings such as a laser power of 80%, a scan speed of 1000 mm / s, a pulse frequency of 40 kHz, a fill pattern “hatched line”, and a fill line interval of 0.060 mm are accepted. These setting contents are transmitted to the controller 2 as print data.

  Returning to FIG. 5, the font selection accepting unit 302 accepts selection of font data to be printed from among a plurality of stored font data. FIG. 7 is a view showing an example of a font selection acceptance screen of the print data generation device 3 according to the embodiment of the present invention.

  As shown in FIG. 7, the selection area 71 accepts selection of font data to be transmitted to the controller 2 together with the print data. For example, when printing on a car number plate, a character string such as “Osaka 300 or 12-34” is to be printed. In this case, the selection of the check box for the font “Mincho” and the character type “Hiragana” is accepted, and the selection of the check box for the character type “basic Latin (half-width alphanumeric symbols)” is also accepted. In the example of FIG. 7, the “currently used character” check box is invalidated, but it goes without saying that it may be selectable. For example, when the “currently used character” check box is selected, the selection of the character type related to “Osaka” currently being used is accepted.

  FIG. 8 is an exemplary view of font data included in the print data of the print data generation device 3 according to the embodiment of the present invention. FIG. 8 shows font data of a total of 188 characters such as Hiragana, English characters (uppercase letters, lowercase letters), symbols, etc., among the Mincho font data accepted on the font selection acceptance screen shown in FIG. This font data is transmitted to the controller 2 together with the print data.

  That is, returning to FIG. 5, the print data generation unit 303 extracts font data corresponding to the font data that has been selected, and generates print data that includes the extracted font data and a predetermined character string that has received the settings. To do. The print data transmission unit 304 transmits the generated print data to the controller (laser light control unit) 2.

  Thus, it is not necessary to store all font data in the controller 2, and the controller 2 can receive print data including font data necessary for printing. When the font data is different, or when the font data is not stored, the desired font can be printed in any case.

  The timing for generating the print data including the font data for which the selection has been accepted may be any timing as long as it is a timing for transmitting the print data to another laser marker, controller, etc. after accepting the print data setting.

  The font data extracted by the print data generation unit 303 is not limited to being extracted according to the type of character string as shown in FIG. For example, only font data corresponding to the character itself included in a predetermined character string for which the setting has been accepted may be extracted. In the example of FIG. 7, it is sufficient to extract only font data corresponding to each character of the character string “Osaka 300 12-34”.

  Further, the font data is classified into a plurality of groups and stored in the storage device 33, and the group designation accepting unit 306 accepts the designation of the group by the user, and extracts only the font data belonging to the group that accepted the designation. Also good. As a group that accepts designation, font data is stored for each group, such as “alphabet”, “numeric symbol”, “Hiragana”, “katakana”, “kanji”, etc. By accepting the designation of the group, only the font data belonging to the group is extracted to generate print data. As a result, print data including font data necessary for printing can be received, so there is no need to store large-capacity font data in the controller 2, and even when a different controller 2 is used. It is possible to print with a desired font.

  Note that font data may be classified into a plurality of groups for each language used. For example, for each language used for a character string to be printed, such as “Japanese”, “English”, “Chinese”, etc., the font data is classified into groups and stored in the storage device 33, and the language designation receiving unit 308. The language designation by the user is accepted. Print data is generated by extracting only the font data belonging to the group corresponding to the language for which the designation is accepted. As a result, print data including font data necessary for printing can be received, so there is no need to store large-capacity font data in the controller 2, and even when a different controller 2 is used. It is possible to print with a desired font. Needless to say, the development data is generated for each controller 2 based on the received print data including the font data.

  In addition, font data is classified into a plurality of groups and stored for each language to be used, and language extraction means 309 for extracting and specifying a language used in a predetermined character string whose setting has been received is provided. Only the font data belonging to the group corresponding to the specified language may be extracted. Even in this case, it is not necessary to store a large amount of font data in the controller 2, and even if a different controller 2 is used, it is possible to print with a desired font.

  Furthermore, when the predetermined character string for which the setting has been received is composed of only alphanumeric characters, only font data corresponding to the alphanumeric characters may be extracted. Since it is sufficient to transmit only font data corresponding to alphanumeric characters, the communication load can be reduced and the controller 2 does not require a large storage capacity.

  Further, it may be provided with a font designation receiving means 307 for receiving the designation of font data by the user, and only the font data for which the designation has been accepted may be extracted. Since only necessary font data can be extracted, it is not necessary to store large-capacity font data in the controller 2, and even if a different controller 2 is used, it is possible to print with a desired font. .

  Further, the font data required by analyzing the predetermined character string to be printed based on the information on the character string received by the character string setting accepting unit 301 without accepting the specification of the font data. May be limited. Specifically, an analysis unit 305 may be provided to analyze a predetermined character string for which setting has been accepted, and extract only font data corresponding to characters that can be used. Thus, for example, when the predetermined character string for which the setting has been received is only a character string displayed in hexadecimal, the font data of numbers “0” to “9” and the English characters “A” to “F” Only font data for characters is enough.

  FIG. 9 is a flowchart showing a procedure of print data generation processing of the CPU 31 of the print data generation device 3 according to the embodiment of the present invention. In FIG. 9, the CPU 31 of the print data generation device 3 accepts the setting of information relating to a character string including a predetermined character string to be printed on the workpiece W (step S901). Not only the setting of the character string to be printed, but also the setting for the printing condition is accepted.

  The CPU 31 accepts selection of font data to be printed from among a plurality of stored font data (step S902). Font data extracted or designated by the method described above may be selected.

  The CPU 31 extracts font data corresponding to the font data whose selection has been accepted (step S903), and generates print data including the extracted font data and a predetermined character string whose setting has been accepted (step S904). The CPU 31 transmits the generated print data to the controller (laser light control unit) 2 (step S905).

  The controller 2 that has received the generated print data stores print data including font data necessary for printing. When printing, the controller 2 generates and prints development data based on the print data and font data.

  As described above, according to the present embodiment, it is not necessary to store all font data in the controller (laser beam control unit) 2, and it is transmitted together with print data including font data necessary for printing. Therefore, even when printing with different devices (controllers), the fonts can be unified and printed. Since it is not necessary to transmit all font data having a large capacity together with the print data, the communication load can be reduced, and the controller (laser light control unit) 2 does not need a large storage capacity.

  The present invention is not limited to the above-described embodiments, and various changes and improvements can be made within the scope of the present invention. For example, the transmitted print data may be stored, and an input of a communication command that instructs to change the character string may be received from the outside. In this case, since the character string printed on the workpiece W can be changed based on the input communication command and the font data included in the print data, the controller 2 of the laser marking device 10 can change the character string. By simply sending a communication command, it is possible to refer to the font data stored in the controller 2 and change the character string in a desired font without going through the PC application.

1 Marking head (laser beam scanning part)
2 Controller (Laser light generator and laser light controller)
3 Print data generator (print data generator)
4 External equipment 10 Laser marking device 31 CPU
32 memory 33 storage device 90 portable recording medium 100 computer program 331 font data storage unit

Claims (13)

A laser beam generator that emits laser beam;
A laser beam scanning unit that scans the surface of the placed workpiece two-dimensionally with a laser beam;
Based on print data for printing a character string on the workpiece, a laser light control unit that performs laser printing;
A laser marking device having a print data generation unit for generating print data,
The print data generation unit
A character string setting accepting means for accepting setting of information relating to a character string including a predetermined character string to be printed on the workpiece;
Font data storage means for storing a plurality of font data corresponding to a plurality of different fonts;
Font selection receiving means for receiving selection of font data to be printed from among a plurality of stored font data;
Print data generating means for extracting the font data corresponding to the font data for which the selection has been received, and generating print data including the extracted font data and the predetermined character string for which the setting has been received;
A laser marking apparatus comprising: print data transmission means for transmitting the generated print data to the laser light control unit.   2. The laser marking apparatus according to claim 1, wherein the print data generation unit generates single print data including the extracted font data and information on a predetermined character string.   3. The laser according to claim 1, wherein the print data generation unit extracts only font data corresponding to a character included in the predetermined character string whose setting is received by the character string setting reception unit. Marking device. Font data is classified and stored in multiple groups,
A group designation accepting means for accepting group designation by the user is provided.
The laser marking apparatus according to claim 1, wherein the print data generation unit extracts only font data belonging to a group whose designation is received by the group designation reception unit. Analyzing means for analyzing the predetermined character string received the setting,
3. The laser marking apparatus according to claim 1, wherein the print data generation unit extracts only font data corresponding to a usable character based on a result analyzed by the analysis unit. . For each language to be used, font data is classified into multiple groups and stored.
A language designation accepting means for accepting language designation by the user is provided.
3. The laser marking apparatus according to claim 1, wherein the print data generation unit extracts only font data belonging to a group corresponding to the language whose designation is received by the language designation receiving unit. For each language to be used, font data is classified into multiple groups and stored.
Language extraction means for extracting and specifying the language used in the predetermined character string for which the setting has been received;
3. The laser marking apparatus according to claim 1, wherein the print data generation unit extracts only font data belonging to a group corresponding to a language extracted and specified by the language extraction unit.   3. The print data generation unit extracts only font data corresponding to alphanumeric characters when the predetermined character string for which setting has been received is composed of only alphanumeric characters. Laser marking device. A font designation accepting means for accepting font data designation by the user;
The laser marking apparatus according to claim 1, wherein the print data generation unit extracts only font data for which designation is accepted. The laser light control unit includes means for storing print data transmitted by the print data transmission means,
When a communication command instructing to change a character string is input from the outside, the character string printed on the workpiece can be changed based on the input communication command and the font data included in the print data. The laser marking device according to any one of claims 1 to 9, wherein the laser marking device is characterized in that: A laser beam generator that emits laser beam;
A laser beam scanning unit that scans the surface of the placed workpiece two-dimensionally with a laser beam;
Based on print data for printing a character string on the workpiece, a print data generating device that is connected so as to be capable of data communication with a laser light control unit that performs laser printing, and generates print data,
A character string setting accepting means for accepting setting of information relating to a character string including a predetermined character string to be printed on the workpiece;
Font data storage means for storing a plurality of font data corresponding to a plurality of different fonts;
Font selection receiving means for receiving selection of font data to be printed from among a plurality of stored font data;
Print data generating means for extracting the font data corresponding to the font data for which the selection has been received, and generating print data including the extracted font data and the predetermined character string for which the setting has been received;
A print data transmission device comprising: print data transmission means for transmitting the generated print data to the laser light control unit. A laser beam generator that emits laser beam;
A laser beam scanning unit that scans the surface of the placed workpiece two-dimensionally with a laser beam;
Based on print data for printing a character string on the workpiece, it is connected to a laser beam control unit that performs laser printing so that data communication is possible, and can be executed in a print data generation device that generates print data. A possible print data generation method,
The print data generation device includes:
Receiving a setting of information on a character string including a predetermined character string to be printed on the workpiece;
Storing a plurality of font data corresponding to a plurality of different fonts;
Receiving a selection of font data to be printed from a plurality of stored font data;
Extracting font data corresponding to the selected font data, and generating print data including the extracted font data and the predetermined character string having received the setting;
And a step of transmitting the generated print data to the laser light control unit. A laser beam generator that emits laser beam;
A laser beam scanning unit that scans the surface of the placed workpiece two-dimensionally with a laser beam;
Based on the print data for printing a character string on the workpiece, it is connected to a laser beam control unit that performs laser printing so that data communication is possible, and can be executed by a print data generation device that generates print data. A possible computer program,
The print data generating device;
A character string setting acceptance means for accepting setting of information relating to a character string including a predetermined character string to be printed on the workpiece;
Font data storage means for storing a plurality of font data corresponding to a plurality of different fonts;
Font selection receiving means for receiving selection of font data to be printed from among a plurality of stored font data;
Print data generating means for extracting font data corresponding to the selected font data and generating print data including the extracted font data and the predetermined character string for which the setting has been received, and the generated print data A computer program that functions as print data transmitting means for transmitting to the laser light control unit.