KR840000781B1 - Sewing machine - Google Patents

Abstract

An automatic embroidery or stitch pattern sewing machine is provided with a memory for storing plural blocks of cell pattern information respectively including zone data related inter alia to the locations of triangular or quadrangular zones SA1-SA8 of which a cell stitch pattern is to be formed, and a manual input device for setting up a desired number of stitches to be formed in the zone. Based on the position data stored in the memory and the stitch number data set by the manual input device, a microprocessor connected thereto calculates the positon data of the actual stitch forming positions; and a drive mechanism relatively moves the needle and the workpiece according to the calcualted position data.

Description

Sewing machine

1 is a view showing the appearance of the present apparatus.

2 is a view showing a key board and a display panel of the control device of the present apparatus.

Figure 3 is a block diagram showing the electrical circuit of the control device of the present apparatus.

Figure 4 is an address app showing the address of each element in the electrical circuit of the control device.

5 and 6 are explanatory diagrams for explaining the contents of the data bank installed in the ROM.

7 to 12 are explanatory diagrams of the registers provided in the RAM.

13 to 18 are explanatory views for explaining pattern data stored in a data bank and embroidery patterns formed based on the data.

Fig. 19 is an explanatory diagram for explaining the relative position of the embroidery frame and the sewing machine arm of the processing cloth at the time of setting the area by the operator.

20 to 24 are explanatory diagrams for explaining the instruction contents of the Arrange command of the present apparatus.

25 to 40 are each flowchart art for explaining the operation of the control unit of the present apparatus.

The present invention is to move the sewing machine needle and the processing cloth relative to the embroidery pattern data stored in the storage device in advance, so that the embroidery pattern is automatically formed on the processing cloth by a plurality of seams formed in accordance with the vertical movement of the sewing machine needle. It is about a sewing machine.

Conventionally, in this type of automatic embroidery machine, pattern data consisting of a plurality of seam forming points corresponding to a required embroidery pattern is continuously stored in a storage means such as a through tape, and relative to the sewing machine needle based on the position data. At the same time, the embroidery pattern was formed on the fabric by a number of seams formed with the up and down movement of the sewing machine needle. For this reason, for example, when embroidering a new embroidery pattern on a fabric with a similar relationship to that of the embroidery pattern stored in the paper tape or having a different size, the embroidery pattern stored in the paper tape may be plural. It is necessary to make a paper tape corresponding to a new embroidery pattern by changing the arrangement of letters, symbols, etc., and the spacing of them. The amount of paper tape was also enormous, requiring a large space for its storage. Therefore, when the embroidery pattern is different for each operation, such as the work of the character embroidery such as the initial name of the customer, especially the clothes, etc., the automatic sewing machine cannot be used, and the needle moves up and down by hand operation based on the experience of the operator. The embroidered fabrics were embroidered by moving the fabric, and not only did they require a lot of skill to make beautiful embroidery, but they also had problems such as not being able to obtain a uniformly finished embroidery.

The present invention seeks to eliminate the above-mentioned defects of the conventional apparatus, and the first object is to store a plurality of embroidery pattern data corresponding to characters, symbols, etc. in the storage device in advance, so that at least two or more of them can be arbitrarily selected. At the same time, it is to provide an automatic embroidery sewing machine that can embroider the fabric on the basis of the combination pattern of the selected new character symbol. The second object is to easily set the arrangement direction of the embroidery patterns and their spacings composed of a plurality of characters, symbols, etc. stored in advance, and to embroider the processed fabric on the arrangement direction or the intervals according to the set data. To provide automatic sewing machines. The third object is to provide an automatic embroidery sewing machine which can enlarge or reduce embroidery pattern data such as letters and symbols that have been memorized in advance, and can embroider patterns on the processing cloth based on the enlarged or reduced data. .

Next, the details will be described based on FIGS. 1 to 40 showing one embodiment in which the present invention is embodied in an automatic embroidery machine. In FIG. 1, on the sewing machine table, the industrial sewing base body 2 which consists of the bed 2a and the arm 2b is mounted. The needle plate 3 is mounted on the bed 2a, and a needle hole 3a is formed in the center thereof. The arm 2b is equipped with a needle 4 at the lower end thereof, and a needle bar 5 connected to the swing lever 6 through the needle holder 5a is mounted, and at the front of the arm 2b, the swing lever 6 is mounted. An adjustment mechanism 7 for adjusting the swing amount and a first pulse motor 8 operatively connected to the adjustment mechanism 7 are installed to set the swing amount, and the upper shaft (not shown) of the sewing machine is installed. On the basis of the up and down motion of the needle bar 5 accompanying the rotation and the rocking motion (arrow B direction) of the swing lever 6, the needle 4 is cooperated with a half moon house (not shown) in the sewing base 2. A zigzag seam is formed in the left and right directions (arrow B direction) on the processing cloth 9.

On the rear side of the upper surface of the sewing machine table 1, a pair of right and left mounting frames 10 and 11 made of synthetic resin material such as polyaceta are fixed at a predetermined interval by a plurality of screws. On the sewing machine table 1 and the upper surface, a feed screw 12 and a rotation transmission side 13 are rotatably supported between the mounting frames 10 and 11 so as to extend in parallel therewith. A second pulse motor 14 is attached to one mounting frame 10 so as to rotate the feed screw 12 through a gear mechanism. The other mounting frame 11 is equipped with a third pulse motor 15 for rotationally driving the rotation transmission shaft 13.

The support screw portion 16a of the X-axis movable table 16 is inserted in the feed screw 12 so as to move in the axial direction, and the X-axis movable table 16 includes the feed screw 12 and the rotation transmission shaft ( And a guide pipe 16b and an anterior support portion 16c extending in a direction orthogonal to 13). The Y-axis movable stage 18 is fitted into the guide pipe 16b of the X-axis movable stage 16 so as to move in the axial direction, and the Y-axis movable stage 18 is the rotary transmission shaft 13. It is fixed to a part of the pair of connecting wires 17 connected to the. The embroidery frame 19 made of synthetic resin material such as polyaceta is a ring-shaped processing retaining portion 19b which opens a part of the mounting plate portion 19a to the Y-axis moving table 18 and a part of the outer circumference. And an embroidery frame 20 inserted into the fixing screw 19c and the processing cloth holding part 19b to hold the processing cloth 9 in cooperation with it. Therefore, the embroidery frame 19 holding the processing cloth 9 is oriented in the horizontal direction (arrow) through the feed screw 12, the X-axis moving table 16, and the like based on the rotational drive of the second pulse motor 14. X direction) and orthogonal to the X direction through the rotation transmission shaft 13, the connecting wire 17, the Y-axis moving table 18, etc. based on the rotational drive of the third pulse motor 15. It moves in the direction (arrow Y direction).

On the lower front face of the sewing machine table 1, the previous ON switch 21, the leading edge OFF switch 22, the embroidery start command switch 23, and the emergency stop switch 24 are provided. In addition, the cable 26 which transmits the drive signal of the sewing basic body 2 and the drive signals of the first, second, and third pulse motors 8, 14, and 15 beside the sewing machine table 1. Is connected to the control device 25. The control device 25 has a key board 27 for carrying out programming commands for forming a desired embroidery pattern on the fabric 9 and a display panel 28 for displaying the operation results thereof.

In FIG. 2, the rotation drive command is generated on the right and right sides of the key board 27 in the second and third pulse motors 14 and 15 to move the embroidery frame 19 in the X, Y directions and their respective directions. And a plurality of bobbin moving keys 29 and embroider frames 19 provided for moving in the direction of a 45 degree angle, and when the embroidery frame 19 is out of a predetermined movable area, for validating the operation of the bobbin moving keys 29. Embroidery frame at the time of stopping during the embroidery pattern forming operation of the apparatus due to an accident such as the RLS key 30, the RST key 31 for resetting the control circuit part of the control device 25, the thread of the sewing machine, etc. When moving 19 to the required position, RTN key 32 for generating a command signal, MCHNLOCK key 33 for setting the control mode of the sewing machine by the control device 25, SGLDATA key 34, The SGLSTIT key 35 is arranged. The MCHNLOCK key 33, SGLDATA key 34, and SGLSTIT key 35 are provided with light emitting diodes 33a, 34a, 35a for displaying their control modes to the operator, respectively.

A data key group 36 consisting of a plurality of data input keys is arranged at the left center portion of the key board 27, and on the upper surface of each data key, alphanumeric characters and English letters corresponding to the embroidery patterns, respectively. Symbols (English), Kana (Japanese), and Japanese character symbols are engraved. Instructions on which of these characters to select are given for each data selection key (37), (38), (39). This is carried out by selectively pressing operation 40. In general, when these selection keys are not operated, alphanumeric characters are selected from the above characters. The alphanumeric character is selected by manipulating each key of the data key group 36 after the SHFTL key 41 and the SHFTS key 42, which designate the case of itself, are operated. SPACE key 43, which indicates spaces between character symbols selected by each operation of the data key group as well as data key group 36, respectively, and indicates newline return of each character code string. CR / LF keys 44 are arranged.

At the upper left of the key board 27, the AREA key 45 for setting and inputting a range in which the embroidery frame 19 holding the processing cloth 9 can move without contacting the needle 4, various programming and data Embroidery pattern data corresponding to the ENTER key 46 for instructing the end of the input command code, the CTRL key 47 for instructing the start of various programming command codes, 47 and other special patterns stored in the storage device in advance. PATN key 48 for instructing the pattern data consisting of the PAUSE key for inputting a command to pause the operation of the sewing basic body 2 at the time of completion of the formation of the embroidery seam by the sewing basic body 2 ( 49), a CAT key 50 for inputting a cumulative code filed into the storage device by combining a combination of patterned data having a high frequency of use, and a combination of patterned data carried by the CAT key; To Various program keys such as a LOAD key 51 for inputting a command code to be readout are arranged, and a display shift key 52 for shifting the display of a display device described later installed in the display panel 28 to the left or right by one digit. And 53 are arranged. In addition, the key board 27 invalidates all the input operation results of the DEL key 54 and various operation input keys for invalidating only the operation results of the operation input keys when the operator incorrectly performs the operation of the above-described various input keys. The CAN key 55 is arranged for the purpose. The display panel 28 includes a 16-digit (56 *) dot matrix display device 56 that sequentially displays the input result of the various program key operations by various input operations of the operator, and a plurality of characters and symbols designated by the operator. Pitch data between the seven-digit number indicator 57 of the number of digits (10 units) for indicating the designated date (Arrange command) such as the arrangement direction of the embroidery pattern, etc. a digital display 58 for displaying the pitch command), a digital display 59 for the digits for displaying the data (Mirror command) for specifying the symmetrical movement with respect to the embroidery pattern data selected by the operator, and the operator In the swing direction (B direction) of the two-digit digital indicator 60 for displaying the size (size command) indicating the size of the selected embroidery pattern data, and the needles 4 of the embroidery patterns such as letters and symbols stored in advance. Regarding Standard Regarding the swinging direction (direction B) of the two-digit number indicator 60 for displaying the change data (Width command) for the data, and the needles 4 of embroidery patterns such as letters and symbols stored in advance, A two-digit number indicator 61 for displaying change data (Width command), and two for displaying designated seam number data (Density command) for each divided block of embroidery pattern pattern data such as letters stored in advance. Digit indicator 62 is arranged.

Next, the configuration of the control circuit of the present apparatus will be described based on the block diagram of FIG. The CPU 63 is a central processing unit. The 16-bit address signal output terminal (ADS), the 8-bit data signal and the command code signal data input / output terminals (DB0 to DB7, input / output) input terminals (INT). The data output terminal has a data bus 64 through which a RAM (readable / writeable memory device 65), a ROM (read-only memory device) 66, a PIT (Progoam-able Interal Timer) 67 And I / OIF (input / output interface) 68, respectively, and the address signal output terminal is connected to the address decoder 70 via the address bus 69. The decoder of the address decoder 70 The output is connected to the chip select terminal CS or the address terminals AD0 to AD11 of each peripheral device such as the RAM 65, the ROM 66, the PIT 67, the I / OIF 68, and the like. The address of the peripheral device is assigned (see Fig. 4.) The first, second, and third pulse motors 8, 14, and 15 are provided at the input / output terminals of the I / OIF 68, respectively. phrase First, second and third driving circuits 71, 71 and 73 for moving, sewing driving circuit 74 for driving the sewing base 2 and needle positioning, and a first pulse Position detection device 75 for detecting the origin of the motor 8, the key board control circuit 76 for generating a key code signal corresponding to each key of the key board 27, the display panel 28 The display control circuit 77 and the embroidery start command switch 23 for driving control of each display element are connected, and the emergency stop switch 24 is connected to the INT terminal of the CPU 63.

The CPU 63, the RAM 65, the ROM 66, the PIT 67, and the I / OIF 68 constitute a computer of a stored program method, and the instruction code group stored in the ROM 66 in advance. On the basis of this, control of various input / output devices connected to the I / OIF 68 is performed. In addition, each control signal of various input / output devices connected to the RAM 65, the ROM 66, the PIT 67, the I / OIF 68, and the I / OIF 68 may be changed according to the address map shown in FIG. It is arranged at each address. The ROM 66 is assigned an area of addresses 0000 to IFFF, and an area of addresses 0000 to 7FFF is a control application comprising a main program for controlling the apparatus and a command code group such as various subroutines. The program 66a is stored, and the area of addresses 2000 to 7FFF is allocated as the data bank 66b, and the data bank 66b corresponds to the characters, symbols, pattern symbols, etc. of the key board 27, and the like. A patterned outer group consisting of various embroidery pattern data is stored (see FIGS. 5 and 6).

An area of addresses 8000 to 9FFF is allocated to the RAM 65, and various working register groups 65a and 65b used for controlling and calculating the apparatus are stored at predetermined addresses, respectively ( 7 to 12). PTT 67 is assigned addresses C 000 to CFFF, and 1 / 01F 68 is allocated an area of addresses F000 to FFFF, and output signals TC ₁ , TC ₂ and the input / output of the PIT 67. Each control signal or the like inputted or outputted to the apparatus is assigned to each predetermined bit of the area, and based on those control signals, the first control signal is assigned. The second and third drive circuits 71, 72 and 73 are each drive controlled.

Next, on the basis of the respective figures showing the data contents of the pattern data of FIGS. 5, 6, 13, 14 and 15 for the embroidery pattern pattern data stored in the data bank 66b. Explain. As shown in FIG. 13, for example, when the pattern pattern is made of embroidery pattern data of Japanese character "イ", the origin PO of the pattern data is determined first, and a portion of forming the seam on the character pattern is shown in FIG. As shown in FIG. ₂ , each of the stitch blocks SA ₁ , SA ₂ ... SA ₈ consisting of a triangle or a quadrangle is divided and assigned, and each X of each vertex SD ₁ , SD ₂ . Coordinate values in the Y direction [(X ₁ , Y ₁ ), (X ₂ , Y ₂ )... (Xn, Yn)], and the order of forming embroidery seams for this character pattern is appropriately specified. And the feedback indicating that the basis of the specified order, for example the L Turn | partial value from the data reference point PO to the stitching block SA _1, i.e., the transfer section (the seam does not form (to a feedback block FB _I, and the feedback block FB _I block cord And a stitch block data as angular coordinate values (X ₃ , Y ₃ ) and (X ₄ , Y ₄ ) of the vertices SD ₁ , SD ₄ , and stitches representing stitch blocks for the next stitch block SA ₁ . The block code and the corner vertices SD ₃ SD ₄ of the bottom surface of the quadrangle of the SA ₁ block are stored as one stitch block data as the coordinate values (X ₃ , Y ₃ ) and (X ₄ , Y ₄ ) of the SA ₁ block. Embroidery pattern data of one character pattern is created in such a manner that stitch block data, feed block data, etc. are stored in sequence, and three bytes of each of the leading addresses of the pattern data of each pattern of embroidery are provided. Embroidery frame 19 by the data MASKB which shows the maximum value of the fluctuation amount of the needle 4 in the pattern data in the B-axis (same as the X-axis), and the second pulse motor 14 in the X-axis direction. The maximum amount of movement MASKY of the embroidery special 19 by the third pulse motor 15 in the Y-axis direction is sequentially stored in the MSKKY of the following: The following walking in the control working register area of the RAM 65; Each register group 65a is assigned to a predetermined address (addresses 8000 to 9FFF), i.e., the working register groups are X from the absolute origin position of the embroidery frame 19 at the time of embroidery pattern formation. ABS.X.REG., ABS.Y.REG. (For current position coordinate memory) for storing the movement amount data in the Y-axis direction, and X, Y coordinate values from the absolute home position at the time of embroidery pattern formation ABSO.X.REG., ABSo.Y.REG. (For storing sewing starting point coordinates) AREAMODE.REG., Which stores the mode of the circular mode or the old mode, AEA.REG., Which stores the data at the time of the circular mode setting, and CMNDDATA which sequentially stores the various input command codes based on the operator's key input operation. .REG., CMNDSGN for temporarily storing the movement direction and movement amount of the first, second, and third pulse motors 8, 14, and 15 based on each movement instruction when the embroidery pattern is formed. B.REG., CMNDSGN.X.REG., CMNDSTORED.Y.REG., CMNDSTORED .RFG., Which remembers that each data is output to their CMNDSGN registers, data by the operator's key input operation, or standard control CTRL.REG for storing data, CTRLKEY.REG for temporarily storing control data entered by the operator, CYCLEEND.REG for storing the operation cycle of the device in the cycle end process, and the operation mode of the device. CYCLEMODE to remember whether it is a key input mode or sewing mode. REG., FILEDATA.REG., Which combines the control data entered by the operator with data such as characters and symbols, and FILETABLE.REG., Which stores the address of each data stored in this register. FILEADR.REG for storing the address of FILETABLE.REG., FROMSEW.REG for storing that the operation cycle of the apparatus is a sewing cycle, ISM.REG for storing the internal synchronization mode, and JOG timer in the key routine. JOGTIM.REG, which remembers the status is continuous, KEYINDATA.REG, which sequentially stores the key input code based on the operator's key input operation, and LADRKEY.REG, which stores the address when reading the input code from this register. , LADRBAND.RE., Which stores the address when reading data from the CMNDATA.REG., LADRSEW.REG., Which stores the address when reading data from SEWADE.REG., And data bank 66b. LADRBANK.REG for storing the address at the time of reading each data of the turbine data, MCHNLOCK.REG for storing the lighting state of the light emitting diode 33a, and MMD for storing the driving state of the sewing machine motor (not shown). REG., First, second, and third drive circuits 71, 72 based on the respective commands of CMNDSGN.B.REG., CMNDSGN.X.REG., CMNDSGN.X.REG. OUT.B.REG., OUT.X.REG., OUT.Y.REG., Which count each drive pulse output to 73, ONSTIT.REG., Which remembers that the apparatus is being sewn, light emitting diode 34a. ONALLRTN.REG., The light emitting diode 34a or (35a) in which the RTN key 32 is in the literal state based on the literal command of the RTN key 32 when the lights are turned off together and the RTN is in the ON state ONRTN.REG., Which remembers the literal state based on the luteron command of the key 32, PATNERY.REG., Which stores the numerical data of the key input operation after the operator's PATN key 48, and each of the embroidery patterns Corresponds to the seam formation point SWEDTA.REG for storing a large number of position data, SADRESEW.REG for storing an address for storing each position data in this register, and a key input code based on an operator's key input operation in KEYINDATA.REG. SADRKKEY.REG, which stores the address of SADRKKEY.REG., SADRKKEY.REG, which stores the address when storing various command codes by the operator in CMNDATA.RE. And SGLDATA.REG., SGLSTIT.REG., Etc., which store the lighting states of the light emitting diodes 34a, 35a.

Next, with respect to the apparatus configured as described above, the embroidery pattern of the character `` I ロ ハ '' composed of the Japanese characters イ, ロ, and ハ on the fabric cloth 9 was placed on the fabric 9 according to various operations of the operator. Taking the case where it forms continuously, the detail is demonstrated according to the flowchart shown in FIGS. 25-40. And at this time, the arrangement of the embroidery pattern formed in the fabric 9 and its direction (Arrange), the size of each character constituting the embroidery pattern, the B direction of each character pattern (same as the X direction) The width of the needle (the fluctuation width of the needle 4) with respect to the standard itself, and the various control data symmetrically with respect to the standard itself are based on the angles based on the predetermined standard controller. The control data specified by the data group and designating the pitch between each character is assumed to be specified by the data based on the operator's key operation. In the above description, the Arrange data center is arranged in a straight line in which the reference point P ₃ at the lower left corner of the rectangular area in which the embroidery characters are stored extends in the direction of the arrow AXO as shown in FIGS. 20 to 22. Arrangement designation (AX30) and Size data are arranged in the X, Y direction of each embroidery letter pattern, that is, 8mm in the X direction. 10mm in the Y direction (size 08) pitch data is 10mm interval between each character (pitch10), width data and mirror data is not specified change (width 1.0) (Mirror 00), respectively, Density data The number of seam formations in the stitch block is designated as the fourth sewing (Density 04).

First, when the power is turned on, the program displays the initialization routine 101 and the display panel 28 for initiating various working registers, input / output politics, etc. at the state address 100 as shown in FIG. Devices 56, display devices 57, 58, 59, 60, 61, 62, and display devices such as light emitting diodes 33a, 34a, 35a, and the like. In order to set the fluctuation amount of the display routine 102 and the needle 4 which turn on each display element for a predetermined time, the first pulse motor 8 connected to the adjusting mechanism 7 is connected to the adjusting mechanism 7. The B-axis also returns to the home position set in advance so that the amount of fluctuation caused by the material becomes the material, and the data transmission to CTR.REG. Of standard control data stored in KEYINDATA.REG. Various settings are performed via the main address 105 from the routine 104 or the like which displays the contents of the data on each display device of the display panel 28. If done the operation of the key reaches the monitor loop 106 performs a monitor of whether or not, and the program continues to monitor loop neunda be done to the operation of the operation key. Therefore, after the display routine has turned on all the display elements of the display device for a predetermined time, the B-axis automatic home return routine routine of the first pulse motor 8 is performed. The driving is stopped, and the swing amount of the needle 4 is set to zero, and the dot matrix display device 56 of the display panel 28 displays the respective commands Arrange, Size... Of the standard control data. … The initial letters "Ax", "S", etc., indicating designated codes such as … Each of the indicators 57 to 62 displays the contents of each command of the standard control data. Here, the initial characters of the command codes displayed on the dot matrix display device 56 are embroidered with black hair as shown in FIG. 2 in order to distinguish them from characters representing data on the embroidery of the character to be embroidered. It is indicated by the letter, whereas it is represented by each molecule of white hair (白 拔).

Next, the churning feed key 29 and the RLS key 30 are simultaneously pressed by the operator, and the program exits the monitor loop 106 and the "on" and "off" of the RLS keys are displayed at the JOG key address. Routine (107), JOGA address, and Routine (108), which checks whether the contents of JOGTIM.REG. Are high level (hereinafter referred to as H) or low level (hereinafter referred to as L or less). The main address is passed through the second and third driving circuits 72 and 73 for driving the second and third pulse motors 14 and 15 through the routine 109 for generating driving pulses. Return to and continue monitoring loop again. Accordingly, the second and third pulse motors 14 and 15 are driven on the basis of the pressing operation of the churning feed key 29 and the RLS key 30, and are held in the embroidery frame 19. The fabric 9 is moved relative to the needle 4. At this time, if the churning feed key 29 and the RLS key 30 are continuously pressed by the operator, the program passes through the ruout 109 many times through the same route as described above. Furnace 72, 73 is given a pulse group having a certain period of time determined by the command execution time of the program of the device of the time set by JOGTIME, REG. do. In addition, as described above, the operator selects a plurality of churning-feeding keys 29 and RLS keys 30 installed in a plurality of movable directions in the direction of the arrow, so that the needle 4 is roughly in the virtual center of the annular embroidery frame 20. The embroidery frame 19 can be moved so that the central axis of the position is located.

As shown in FIG. 19, after the embroidery frame 19 is moved, the center axis of the bar 4 is located at the virtual center of the roughly annular embroidery frame 20, and then the operator AREA key 45 When is pressed, the program jumps from the monitor loop 106 to the AREA key address, so that the plane shape of the rutin 110 and embroidery frame 19 which checks the mode of the AREAMODE.REG. The routine display device 56 displays the letter "R" in the transcript display device 56, and continues through the monitor loop 112 for monitoring the state of the AREA key via the AREA1 address. (Completion of movement to the absolute home position of the embroidery frame 19).

The operator then calculates a numerical value representing the range of movement of the embroidery frame 20 with respect to the needle 4, as shown by 19 degrees (from the distance Rh from the needle 4 to the inner diameter of the embroidery frame 20). Calculate the distance Romax by subtracting 1/2 of the maximum value Bmax of the needle swing amount), for example, when the value is 10 cm, the operator operates the key "R", "I" and "O" by the key operation of the data group 36. Program, the program stores the 'digital' data based on the key operation in the rutin 113 of the monitor loop 112, and the numerical data of the numerical value data is dotmetric. The routine returns to the main address via the routines 115 for clearing each register of the routines 114, ABS.X.REG., And ABS.Y.REG. Therefore, at this point, the dot matrix table market value 56 displays "area setting data" RIO "following the control specification data of each standard control data of AX, S, P, W, M, D. Is done. In addition, the registers of ABS.X.REG. And ABS.Y.REG. Are cleared by the rutin 115 so that the absolute origin position of the embroidery frame 19 with respect to the needle 4 is set. The change of the relative position from the absolute origin position of the embroidery frame 19 is monitored by ABS.X.REG., ABS.Y.REG, and the embroidery frame 19 sets the movable area set with respect to the needle 4. It is forbidden to move beyond (area setting completed).

Next, the embroidery frame depends on whether or not the shape of the embroidery pattern which the operator intends to form on the processing target 9 is in the horizontal direction (embroidery pattern extending in the X-axis direction (or the embroidery pattern extending in the longitudinal direction or Y-axis direction)). Assuming that the embroidery origin position is different from the absolute origin position on the workpiece fabric (9) held at (19), and that the churning feed key 29 is properly operated, the program returns the JOG key address from the monitor loop 106 as described above. The sum of the squares of the data of the routines 107a, ABS.X.REG., And ABS.Y.REG., Which jumps to FIG. 38 and checks the contents of the routines 107 and AREAMODE.REG. ABS.X) ² + (ABS.Y) ² and the Lou tin (107b), Lou tin (107C) to determine the magnitude of the respective data calculated by the Lou tin for computing a square (Romax) ² of the Romax After returning to the main address via JOGA address, Routine (108), (109), etc. Thereafter, the program is operated on the basis of the pressing operation of Chondong Yisong Key (29). Turn the path through each rutin.

Therefore, the operator can move to the embroidery start position most suitable for each embroidery pattern which is to be embroidered on the fabric 9 held on the embroidery frame 19 by selecting and operating a plurality of chute transfer key 29.

When the relative amount of movement of the embroidery frame 19 from the absolute origin position is larger than the value stored in AREA.REG., The program causes the display data of the dot matrix display device 56 to blink in the rutin 107c. Since it is to be returned to the main address via the tin 107d, the second and third pulse motors 14 and 15 are not driven even if the chute feed key 29 is pressed by the operator. The frame 19 does not move, so that the embroidery frame 19 and the needle 4 are not in contact with each other (the completion of the movement of the embroidery frame 19 to the embroidery start position).

Next, when the user wishes to form an embroidery pattern based on a controller (e.g., pitch 05) different from the standard (pitch 10) for the spacing of each character pattern in the standard controller, the operator presses the CTRL key (47). When the alphanumeric characters "P" key, "O" key, "5" key, and ENTER key 46 of the data key group 36 are sequentially operated, the program is assigned to the CTRL key address in the monitor loop 106. After that, the CTRL key routine shown in FIG. 32 jumps. Then, the program checks the operation contents of the operation key operated after the CTRL key 47 from the routine 116 storing the key code of the CTRL key 47 in KEYINDATA.REG. 117b), operation of the routine 119a and the ENTER key 46 which store the CTRL1 and the keycode signal based on the operation in KEYINDATA.REG. And display the numerical data on the dot matrix display device 56. The keycode signal based on the KEYINDATA. REG. At the same time, the routine 118 and the key code signal based on the operation of the digits are stored in the KEYINDATA.REG., And the routine 119a for displaying the digit data on the dot matrix display device 56 ( 119b) to the CRTL for numerical data stored in KEYINDATA.REG. Routine 120 stored in the REG., And return to the main address via the routine Routine 121 to check whether the operation for the designation of the control roller by the above-described key operation is inconsistent with the predetermined designation data. Then the monitor loop 106 is continued again.

Therefore, as shown in Figs. 9 to 11, the keyed signal is sequentially stored in KDYINDAAT.REG. Based on each key operation for designation of the controller, and at the same time CTRL.REG. The numerical data based on the operation is stored in place of the numerical data of the standard controller, and the digit number display device 56 displays "P" following the display data. Accordingly, the dot matrix display device 56 displays "AX, S, PW, M, D, R _M , P", and the display of the digital display 58 changes from "10" to "05" (controll data). Change of designation).

Subsequently, for example, in order to form embroidery patterns of the Japanese character "Iloha" on the fabric 10, the program sequentially selects each key corresponding to the Japanese character "Iloha" from the data key group 36. The monitor loop 106 jumps to the DATA key address (FIG. 34) and, based on the operation of each data key, returns a keycode signal corresponding to the key. Routine 122 stored in REG., Routine 123 for displaying characters corresponding to the manipulated keys on dot matrix display device 56, and KEYINDATA. CMNDDATA based on data stored in REG. Routine 124 stored in REG. And pattern data corresponding to each character pattern selected by the key operation are read out from data bank 66b in ROM 66 and processed based on this data and the control data. Routine 125 for checking in advance whether or not the amount of movement of the embroidery frame 19 when forming the embroidery pattern on the fabric 9 is within the range of numerical data set by the area setting, and the main address. The return to the monitor loop 106 is again followed by a return money corresponding to the number of operations (3 times) of each of the keys, followed by the modulator loop 106 again.

Therefore, as shown in Fig. 2, the dot matrix number display device 56 displays the expression AX, S, P, W, M, R ₁₀ , P, Y, L, H by the rutin 123. KEYINDATA at the same time. REG. And CMNDDATA. REG. Each instruction code based on each key operation is stored sequentially (see FIGS. 9 to 11). In addition, the maximum value of each movement amount in the X and Y directions of the embroidery frame 19 when the embroidery pattern is formed by the patterned data selected by the data bank 66b by the rutin 125 is calculated in advance. When the calculated value exceeds the movable range set based on the area setting, the data display part of the dot matrix device 56 blinks to inform the operator that the operation is missed (completion of the selection command of the embroidery pattern pattern data).

Here, when the operator presses the embroidery start command switch 23 to form the embroidery pattern seam of the Japanese character イ ロ ハ mentioned above on the fabric cloth 9, the program is executed in the monitor loop 106. Jump to SEW key address displayed on the page, SEW00 address (126), ABS. B. REG., ABS. X. REG., ABS. A ABSo that stores the absolute position coordinate data of the B, X, and Y axes at the start of embroidery. B. REG., ABSo. X. REG., ABSo. Y. Routine 127 to send to the REG, the CMNDDATA. LADRCMND to store the address for sequentially reading the contents of the REG. REG. On CMNDDATA. Routine (128), SEW address (129), and LADRCMND. CMNDDATA specified by the address stored in REG. Routine 130 for determining the contents of REG., CMNDDATA. LADRCMND to read the contents of REG. It reaches up to the rutin 131 which increments the contents of REG. And returns to the SEW 10 address 129 again, and then the CMNDDATA. CMNDDATA based on the contents of the command code stored in REG. Routine (132) to update contents of REG., LADRCMND. After returning to the SEW 10th address 129 through the rutin 133 which increments the inner part of CREG., It passes through the ruout 130 and CMNDDATA. Position coordinate data which reads the pattern data stored in the data bank 66b in advance based on the pattern data command code stored in the REG. And forms each feed block by reading as shown in FIGS. 15 to 18. Group SD ₁ (X ₁ , X ₁ ), SD ₂ (X ₂ , X ₂ ). And CMNDDATA. Seam formation point position data group SN ₁ , SN ₂ , SN ₃ , SN ₄ ... Based on various control data stored in REG. And the embroidery frame 19 is moved to the embroidery frame SS ₁ , SS ₂ , SS ₃ , SS ₄ . The position of the embroidery frame moving position and the embroidery frame B ₁ , B ₂ , B ₃ ,... When the embroidery frame is moved to the movement position. Is calculated, and the result of the calculation is obtained from SEWDATA. Routine 134 sequentially stored in REG., LADRCMND. Routine (135) which encloses contents of REG., FROMESEW. Routine (136), SEWDATA to build H at REG. LADRSEW which stores the address for reading the contents of REG. Routin (137), which remembers the leading address of REG., Goes to SEW 20.

Thus, CMNDDATA. Each input command code stored in the REG. Is sequentially read from the start command code of the first address to the pitch command code, and the Japanese character "I" command code, and the SEWDA-TA. In REG., Each data (second, third, and first pulse mowers for moving the embroidery frame 19 and the needle 4 to a position corresponding to each seam formation position of the embroidery pattern of the Japanese letter "イ" is shown. The number of driving pulses for driving the rotors 14, 15, and 8 and the code code group thereof is stored.

LADRSEW jumped back to SEW20 (138). SEWD-ATA specified by the address of the REG. Routine (139), SEWDATA. Which read and discriminate instruction contents of REG. LADRSEW to read the next instruction code memorized in REG. Through the rutin 140 to increment the contents of the REG., The ruout 139, the SEW address 141, and the MMD. Routine 142 which checks whether or not H stands in REG, second and third for moving the embroidery frame 19 in the X and Y-axis directions based on the contents of the feed command code in SEW-DATA.REG. Routine 143 which drives pulse motors 14 and 15 of 3, LADSEW. Rutin (144), SGLSTIT which increments contents of REG. Return to SEW 20 (138) via the routine (145) to check whether H is standing in the REG.

Therefore, the SEWDATA. The star art command code and feed command code stored in the REG. Are read out, and the embroidery frame 19 is embroidered at the starting point of the embroidery frame 19 as shown in FIG. 16 with respect to the center position of the needle 4 based on the feed command code. The second and third pulse motors 14 and 15 are moved from the patterned data origin P ₀ to the SS ₁ position.

In addition, the program stores an MMD for storing information on whether the sewing mechanism movement command signal MMD is output from the SEW20 address 138 to the rutin 139, SEWS address 146, and the sewing mechanism driving circuit 74. REG. Routine 147 that checks whether H is standing on, SEWDATA. The driving pulse is output to the second and third driving circuits 72 and 73 for driving the second and third pulse motors 14 and 15 based on the stitch instruction stored in the REG. Ruutin (148), LADRESEW. Rutin (149), MCHNLOCL which increments contents of REG. REG., SGLDATA. REG., SGLSTIT. Routine 150 which checks the contents of each register such as REG, Routine 151 which outputs sewing mechanism movement command signal MMD to re-drive mechanism 74, etc., is returned to SEW20 address 138 again. .

Therefore, the SEWDATA. The sewing machine driving command signal MMD is outputted to the sewing machine driving circuit device 74 on the basis of the first stitch command stored in REG. And the driving of the sewing base 2 is started. At this time, since the embroidery frame 19 is moved to the predetermined position SS ₁ for forming the first seam based on the feed command code, the drive to the second and third drive circuits 72 and 73 is performed. The pulse is not output, and the drive pulse signal for setting the drive adjustment mechanism 7 is output to the first drive circuit 17 so that the swing amount of the needle 4 becomes B ₁ in FIG.

In addition, the program is based on the second and third drive circuits 72 based on the next stitch command code in the rutin 138, the SEWS address 146, the rutin 147, and SEWDATA.REG. ), Routine 152 for calculating the sewing machine motor speed command signal most suitable for outputting to sewing drive circuit 74 according to the number of driving pulses output to 73, and the MOSPD calculated by the routine in advance. Routine 153 for checking whether the four sewing machine motor speed command signal generation circuits MOSPD 1 to 4 prepared for output to the sewing machine driving circuit 74 are in the range of MOSPD 1 to 4, and the most suitable speed command to the MOSPD 1 to 4 The output of the output signal for validating the signal generating circuit 154 is outputted by the routine sewing drive circuit 74 to the up and down movement of the needle 4, and the needle 4 is processed by the fabric ( 9) Synchronization signal SYC and internal synchronous mode based on NDLUP signal on needle Emitter (ISM.REG.) Lou tin (155) to check whether the information matches, SEWDATA. Routine 156 and LADRSEW which output drive pulses to the first, second and third drive circuits 71, 72 and 73 based on the stitch command code of REG. Routine (157) which increments contents of REG., SGLSTIT. REG., MCHNLOCK. Routin (158) checks the contents of REG.

Therefore, the SEWDATA. The sewing machine motor speed command signal is output to the sewing machine drive circuit 74 based on the first stitch command stored in REG. The seam by the first stitch command is the first seam position on the fabric 10 ( SN ₁ ) is formed above. In addition, when the needle 4 emerges from the processing cloth 9 at the first seam formation point after the seam formation, the position corresponding to the first seam formation point SN ₁ of the embroidery frame 19 is SS _1. ), The driving pulse signal for moving to the position SS ₂ corresponding to the second seam formation point SN ₂ is SEW-DATA. Based on the second stitch command stored in REG., The first, second, and third drive circuits 71, 72, and 73 are output to the first, second, and third pulses. Setting the swing amount of the needle 4 and the embroidery frame to form the second seam at the second seam forming point position SN ₂ on the fabric 9 by means of the rotors 8, 13 and 15. Driving in the X, Y axis directions in 19) is performed.

In addition, the program is SEWDATA which is read out sequentially by the rutin 139. REG. In response to this content (stitch command or feed command), the path through the above-described SEWS address 146 or SEWF address 146 is set to SEWDATA. Rotate as many times as the number of instructions stored in REG. Therefore, SEWDATA. Based on each instruction stored in the REG., The embroidery frame 19 is intermittently moved at each seam formation to a position SS ₃ , SS ₄ ... Corresponding to the seam formation point positions SN ₃ , SN ₄ ... In addition, the needle 4 is set such that the seam is formed at a position corresponding to each seam formation point (SN ₃ , SN ₄ ...), And each seam is formed on the fabric cloth 9. An embroidered seam of "イ" is formed in "Iloha".

In addition, the program outputs the needle positioning signal to the rutin 159 and sewing drive circuit 74 at the SEW 20 address 138 with the ruout 139, ONSTITCH.REG. And FRO MSEW.REG. Lutin (160), SGLSTITCH.REG. Or outputs driving pulses to the second and third drive circuits 72 and 73 based on the routine 161a for checking whether H is standing in SGLDATA.REG. And the pitch command of the control data. Then, the embroidery frame 19 is jumped to the SEW address 129 via the rutin 161b which moves the next character pattern data Japanese character " LO " to the pattern data origin P ₀ position.

Therefore, after the embroidery pattern formation of the Japanese letter "I", the needle 4 is stopped by the rutin 160. In order to form the next embroidery pattern " lo " by the rutin 161b after the needle stop of the needle 4, the Pitch instruction of the pattern data is read out and the embroidery frame 19 is moved based on the instruction.

Thereafter, the seam of the pattern of Japanese character "Ro" is formed on the processed cloth 9 similarly to the embroidery pattern formation of the Japanese character "イ" mentioned above.

Then, as shown in Fig. 17, the stitch blocks SAn, SAn + 1... As for the parts of the back and the like, the seam formation point positions SNn-1, SNn, SNn + 1... The position data for moving the embroidery frame 9 (19) to the result position of the calculation is SEWDATA. Since it is stored as each stitch command of REG., When forming a shooter pattern based on the stitch command, the first pulse porter 8 for setting the swing amount of the needle 4 is fixed at the origin position. The needle 4 is not swinged, and only the embroidery frame 19 is moved to the seam forming position by the second and third pulse motors 14 and 15 in a jig shape (see Fig. 18). Embroidery patterns and seams are formed on the fabric 9.

After the formation of all the embroidery patterns, the program returns to SEW 10, 129, and the rutin 62, CYCLEEND, which moves the embroidery frame 19 from the rutin 130 to the embroidery start position of the first character pattern. Going back to the main address via Ruutin 63, who sets H in REG., And Monitor Loop 106 continues.

Therefore, after forming the seam of the embroidery pattern of the Japanese character "Iroha" programmed by the operator as described above, the embroidery frame 19 is moved to the embroidery start of the original character pattern, so that the new fabric 9 is prepared by the operator. Once set in the embroidery frame 19, the seam of the embroidery pattern as described above can be formed again.

And, during the formation of each of the above-described letters, the embroidery frame 19 is not able to complete the movement of the embroidery frame 19 while the needle 4 is in the state of exiting from the fabric 9, When the amount of movement in the Y direction is large, the driving command signal is output to the sewing machine driving circuit 74 again by outputting a needle stop signal to the sewing machine driving circuit 74. Routine 165 or the like to stop the driving of the sewing base (2).

In the example of forming the embroidery pattern of the Japanese character "Iloha", the Arrange command (A x 30) of the control data as shown in FIG. 22 is shown as control data for setting the character arrangement. Although the character array has been specified, when the control data is changed to AX11, AY20, for example, by the same key operation as in the above-described pitch change, each Japanese character "IROHA" shown in Figs. 23 and 24 is shown. An embroidered pattern having an arrangement of? Can be formed on the fabric 9, and if the control data is changed, the 21st in each of the linear directions (AX3, AX2… AY-1, AYO…) shown in FIG. Embroidery patterns of each character can be arranged so that each reference point P1, P2-for each character pattern data shown in the figure is open. In addition, the size command is also designated by the key operation in the horizontal direction (X-axis direction) of the pattern in the horizontal direction (X-axis direction) from 01 to 99 mm, so that the size command specified by the routine 135 of the flowchart art in FIG. Each data of the size corresponding to the data is stored in SEWDATA.REG sequentially, and the embroidery pattern having the size based on the above instruction is formed on the fabric 10 by each of the rutins after the rutin 135.

In the above embroidery example, the size of each Japanese character is the same size for the Japanese character イ ロ ハ, but each character is the same size according to the size command based on the standard controller, but only the Japanese character ㅁ is expanded. If the user wants to reduce the size, after the data key input operation of the Japanese character "イ" mentioned above, the size command corresponding to the requested enlarged / reduced data is issued similarly to the command operation of each control data mentioned above, Data key input operation, and then the data key input operation similar to the Japanese character "イ" is performed for the Japanese character "ハ".

As for the other control data, the control command for each embroidery pattern can be changed by key input operation of each control command as described above between the embroidery pattern data.

Incidentally, in the above-described embroidery pattern formation example, the Japanese character "Iloha" was explained, but in addition to each character symbol (English alphabet symbol, alphanumeric character, Japanese character symbol, Japanese character) displayed on each data key group of the key board 28, Various pattern data corresponding to each embroidery pattern such as Chinese characters or other special characters or patterns are stored in the data bank 66b of the ROM 66, and one or more of them are selected by the operation of the PATN key 48. According to the flow chart art shown in PATN kiiroutin of FIG. 33, the operator can form the selected embroidery pattern on the fabric 10 by selecting and manipulating each pattern data as in the case of the Japanese character イ ロ ハ. have. In addition, each pattern data is also stored in the data bank 66b for hiragana characters and handwritten characters, and the selection keys 37, 38, 39, SHFTL key 41, and SHFTS key 42 are stored. By using together, an operator can select those pattern data arbitrarily. In the embroidery pattern formation of the Japanese letter "Iloha", the light emitting diodes 33a, 34a, 34a of the MCHNLOCK key 33, the SGLDATA key 34, and the SGLSTIT key 35 are all. In the unlit state, the sewing mechanism driving circuit 74 is made effective by the operation of the embroidery start command switch 23 as described above, and an embroidery pattern of Japanese character "Iloha" is formed on the fabric 10, When the MCHLOCK key 33 is pressed and the light emitting diode 33a is lit by the rutin 166 of FIG. 35, when the sewing start command switch 23 is pressed, the program is the SEWKEY rutin (150 of FIG. 39). ) Jumps directly to the SEW20 address 138 without passing through to the rutin 151, so that the drive signal is not output to the sewing drive circuit 74, and the program thereafter is the rutin 139, 147, and 148. From (150) to Ruutin (148) via a looping back to SEW 20 (138) Since the embroidery frame 19 is moved by the rutin 148, only the second and third pulse motors 14 and 15 are driven. When the SGLDATA key 34 is pressed and the light emitting diode 34a is turned on by the lutin 167 of FIG. 36, the program jumps to the main address by the lutin 161a. After the embroidery pattern is formed, the sewing operation is paused, and the SGLSTIT key 35 is pressed, and when the diode 35a is lit by the rutin 169 of FIG. 1 45), the program returns to the main address, and stops after executing only the first feed command of the above-described Japanese character "イ", and when the embroidery start command switch 23 is pressed again, the program executes the routine at the routine Routine 150. After returning to the main address again through 170 and 171, only the first stitch instruction of the Japanese character "I" mentioned above is stopped after execution.

In the above-described embroidery pattern formation example, various program data such as the program contents "R10, P05, IROHA", such as area setting, pitch specification, embroidery character setting, etc., by operator's various key operations are stored in the RAN 65 file. Can be stored in REG. In other words, when the CAT key 50 is pressed, the program jumps to the CAT key routine of FIG. 29, and each program data is stored at a predetermined address of FILE.REG in the RAM 65 by the routine 172 or the like. When the LOAD key 51 is pressed, the program jumps to the LOAD key routine in FIG. 28 and the FILE. The contents of the profit program data stored in the REG. Is KEYINDATA. It is read again in REG. Therefore, for example, after the operator has formed the embroidery pattern of the Japanese character `` Iloha '' shown in the above-described embroidery pattern formation, the program data contents are stored in the File area by the press operation of the CAT key. When an embroidery pattern consisting of an embroidery pattern and another letter symbol is formed on the fabric 9, the operator again forms the embroidery pattern of "Iloha" described above on the fabric 10, and the operator presses the LOAD key ( By simply pressing 51), the program for embroidery pattern of "Iloha" can be executed, and there is no need to write a new program.

Next, during the embroidery pattern formation of the Japanese character "Iloha" described above, a thread break signal (BROKEN signal) from a thread break detection device (not shown) or an emergency stop signal based on the operator's operation of the emergency stop switch 24. The case where the input of the driving signals to the sewing drive circuit 74 and the first, second, and third drive circuits 71, 72, and 73 by the (EMERGENCY signal) is stopped will be described. .

First, when the input of each drive signal is stopped based on the generation of the actual cutting signal shortly after the start of embroidery pattern formation of the Japanese character `` Iloha '' described above, the operator presses the RTN key 32, and the program monitors. Rutin 174, SGLDATA key, which jumps from the loop 106 to the RTN kiruutin of FIG. 40 and checks whether the needle 4 is in the position (needle position) exiting the processing cloth 9 (34) or ABS storing the current position coordinate data of the routine 175 and embroidery frame 19 for checking whether the light emitting diodes 34a and 35a of the SGLSTIT key 35 are turned on. X. REG., ABS. ABSO that stores the X, Y coordinate values and embroidery start position coordinate data of Y.REG. X. REG., ABSO. Routine 176 for calculating the movement amount from the X, Y coordinate value of Y. REG. To the control start point, and the second and third drive circuits 72 based on the movement amount calculated by the ruout 176. Routine 177, RTN00 address 178, and first pulse motor 8 which drive signals to the 73 and drive the second and third pulse motors 14 and 15, respectively. The monitor loop 106 is continuously rotated again through the routine 79 for transmitting the drive signal to the first drive circuit 71 and the main address to move the to the home position.

Therefore, the embroidery frame 19 is moved to the sewing start point ABSo by the pulse motors 14 and 15, and the adjustment mechanism 7 is moved to the home position where the swing amount of the needle 4 is free. There, the operator removes the seams already formed on the work fabric and the work fabric 9 or replaces the work fabric, and presses the seal start command switch 23 again to start the embroidery work from the beginning. When the needle 4 is in a position where the needle 4 is not pulled out of the fabric at the time of the thread cutting signal, the embroidery frame 19 will not move to the sewing start point by the above-described rutin 174. Although it is prohibited, the needle 4 may be automatically moved to the needle position, and then the embroidery frame 19 may be moved to the sewing start point.

After the completion of the embroidery pattern of the Japanese letter "I" and soon after the formation of the embroidery pattern of the Japanese letter "RO", the input of each driving unit is stopped due to the generation of the disconnection signal. First, by pressing the SGLDATA key 34 to turn on the light emitting diode 34a and then pressing the RTN key 32, the program jumps from the monitor loop 106 to the RTN key routine, and then the rutin 174. ), (175), LADSEW.REG storing the address to read the contents of the routine (180), RTN address (181), and SEWDATA.REG. To check whether H is standing in CMDSTORED.REG. Rutin (182), LADSEW. The contents of the address designated by the contents of REG. Are read, and the driving signals to the second and third driving circuits 72 and 73 based on the read data are sent to the CMNDSGN.B. Routines (183) stored in each register of REG., CMNDSGN.X.REG., CMNDSGN.Y.REG. (1) Checks the instruction contents of the routines 184 and SEWDATA.REG. Routing to send the driving instruction to the first, second and third driving circuits 71, 72 and 73 based on the contents of the rutin 185, RTN address 186 and CMNDSGN registers. Tin 187, SGLSTIT key 35 jumps back to RTN 201 181 through rutin 188, which checks the lighting state of light emitting diode 35a, and then rutin 182, 183. 184, 185, 186, 187, and 188 continue the loop, called RTN 20 (181). After that, when the feed command stitch command and other start command (MASK command code) in the rutin 185 are read out from SEWDAT.RFG., The program determines whether the light emitting diode 34a or 35a is lit. The routine returns to the main address through the ruout 189 to be checked and continues to turn the monitor loop 106.

Therefore, based on the pressing operation of the operator's RTN key 32, the embroidery frame 19 is moved in the reverse direction from the position at which the embroidery frame 19 is stopped, in relation to the above-described movement trajectory of the embroidery pattern former (character). Stops at the beginning of the embroidery pattern. Thereafter, the operation is performed by threading or removing the seam of the Japanese character " Ro " formed on the fabric 9, and pressing the sewing start command switch 23 again. Is initiated. Then, input of each drive signal is stopped while the embroidery frame 19 is completely moved to the respective positions of the positions SS1, SS2, ... corresponding to the seam forming positions SN1, SN2, ... shown in FIG. 16 and FIG. In the case of the program, each of the contents of the OLT.B.REG., OUT.X.REG., OUT.Y.REG. In the rutin 180 is converted to CMNDSGN.B.REG., CMNDSGN.X.REG., CMNDSGN. Since the route jumps to the RTN address 181 through the rutin 190 stored in Y.REG and the rutin 191 inverting the sign of each CMNDSGN register, the embroidery frame 19 is described above. Similarly, the Japanese character `` RO '' is returned to the sewing start point.

Next, at the time of forming the embroidery pattern of the Japanese letter "Iloha" described above, the state in which the majority of the embroidery seams of the embroidery pattern of the Japanese letter "I" is formed, for example, as shown in FIG. 15, the embroidery frame 19 forms the seam. It is located at the position SSn + 2 corresponding to the point SDn + 2, and on the workpiece fabric 9, SN1, SN2... When the pressure of each drive circuit is stopped based on the actual cut signal in the state where the seam is formed up to each seam forming point of the light source, the SGLSTIT key 35 is pressed to turn on the light emitting diode 35a, and then the RTN key is pressed. Pressing (32), the program jumps from the monitor loop 106 to the RTN kiroutine, and the routines 174, (1 75), (180), RTN addresses (181), and rutin (182). , 183, 185, RTN30 address 186, routine 187, 188, etc., return to the main address again to continue the monitor loop 106.

Therefore, the embroidery frame 19 stopped at the position SSn + 2 corresponding to the seam formation point SNn + 2 is the seam formation point SNn adjacent to the seam formation point SNn + 2 based on the pressing operation of the RTN key 32. It is moved to the position SSn + 1 corresponding to +1. If the embroidery frame 19 is not moved to the position SSn + 2 corresponding to the seam forming point SNn + 2, the program is assigned to the RTN 30 via the ruout 180 through the ruouts 191 and 192. Since the path jumps to 186, the embroidery frame 19 is reliably moved to the position SSn + 1 corresponding to the seam formation point SNn + 1 as described above. Then, the RTN key 32 is pressed, and the program executes the path as described above, namely, the rutin 174, 175, 180, 182, 183, 184, 185, and 187. Continue to the monitor loop 106 again.

Therefore, the operator can move the embroidery frame 19 to the well-shaped SSn corresponding to the seam formation point SNn in which the seam is actually formed by pushing the RTN key 32 appropriately. Then, the embroidery frame 19 is moved to the above-mentioned SS point, and then the SGLSTIT key 35 is pressed to cause the light emitting diode 35a to be disturbed, and the sewing start switch 23 is pressed again to press the Japanese letter "I". Sewing can be resumed at the seam formation point SNn.

As described above in detail, the present invention stores a plurality of embroidery pattern data such as letters and symbols in a storage device in advance, and provides a pattern selection means for arbitrarily selecting the embroidery pattern data stored in the storage device. Setting means for setting the arrangement direction and spacing of each embroidery pattern data selected by the pattern selection means, and an enlargement / reduction means for expanding and contracting the selected embroidery pattern data, and each embroidery designated by the setting means and the hospitality reduction means. Since the fabric is moved based on the pattern data and the embroidery pattern is automatically embroidered on the fabric, the various letters, symbols, etc. of the embroidered pattern formed on the combination of letters, symbols, etc. At least one of the gaps and the size of the arrangement direction is easy to different embroidery patterns In addition, the storage device can only store embroidery patterns such as letters and symbols corresponding to the embroidery pattern to be sewn, so that the storage device can be made small and processed without requiring the operator's skill. Excellent effect, such as being able to form a beautiful and uniform embroidery pattern on the heavens.

Claims (1)

Changing the relative position between the needle and the processing cloth holding means having seaming forming means for forming a seam in the processing cloth and having a half moon cooperating with the needle, which is moving up and down, and the processing cloth; And at least one of the driving means connected to either of the seam forming means and the processing cloth holding means, and the pattern data of which one pattern is formed by a plurality of position data indicating a relative position between the needle and the processing cloth holding means. An operation means capable of arbitrarily setting an interval and an arrangement direction between the first storage means for storing at least two and the pattern formed by the pattern data stored in the first storage means, and the first storage means. Second storage means for storing the stored pattern data and the setting data set by the operation means, and the vertical movement of the needle of the seam forming means. And a control device for sequentially taking out each pattern stored in the second storage means and controlling the driving means based on the extracted data.

Images