This Application claims priority to Japanese Patent Application No. 2007-040326, filed Feb. 21, 2007, the content of which is hereby incorporated herein by reference in its entirety.
The present disclosure relates to a sewing machine and a computer-readable recording medium with a program that controls the sewing machine. More specifically, it relates to a sewing machine capable of practicing sewing and a computer-readable recording medium with a program that controls the sewing machine.
Conventionally, in quilting-sewing by which a batting is put between an outer material and a lining material so that these materials then may be sewed along a stitch pattern such as a straight line or a curve, free motion sewing has been carried out to form stitches by arbitrarily moving the work cloth manually by a user.
In this type of free motion sewing, to prevent stitches from looking unattractive due to non-uniformity in the pitch of the stitches, it is preferable to provide uniform stitch pitches as much as possible in sewing. However, it is difficult for a beginner to sew two pieces of work cloth in such a manner as to provide roughly uniform stitch pitches for the pieces while moving them in a desired direction.
To address this problem, it has been proposed that a work of sewing performed by a highly skilled person be recorded so that the recorded information may be reproduced in later sewing. For example, a teaching-purpose embroidering sewing machine described in Japanese Patent Application Laid Open Publication No. Hei 5-5262 is equipped with a tablet and a cursor which are used to detect the position information of a movement frame (which corresponds to an embroidery frame). In this teaching-purpose embroidering sewing machine, the cursor is fixed to the movement frame over which a piece of cloth is stretched, so that the position information of the movement frame that is moved by the skilled person is detected from the tablet and is stored. Based on this stored data, a drive mechanism for the movement frame is driven, to repeatedly reproduce the work of embroidery sewing by the skilled person.
However, because the apparatus disclosed in Japanese Patent Application Laid Open Publication No. HEI 5-5262 records the position information of the movement frame, the apparatus cannot be used in free motion sewing, in which the user moves a piece of work cloth in sewing without using a movement frame. The apparatus has another problem that, to practice free motion sewing, an extra piece of work cloth and a thread is necessary for test-sewing.
The present disclosure addresses these problems. It is an object of the present disclosure to provide a sewing machine that can repeatedly practice free motion sewing without requiring a piece of work cloth or a thread for test-sewing, and a computer-readable recording medium with a program that controls the sewing machine.
To address the above problems, a first aspect of the present disclosure provides a sewing machine comprising a needle bar that is equipped with a sewing needle at a lower end of the needle bar, a presser bar that is equipped with a presser foot at a lower end of the presser bar which holds down a work cloth, a sewing machine motor which is a driving source that drives the needle bar in an up and down direction, and a switching device that switches between a normal mode in which the needle bar is driven in the up and down direction to form stitches and a practice mode in which the sewing machine is operated in a condition where at least the needle bar is not driven.
A second aspect of the present disclosure provides a computer-readable recording medium storing a sewing machine control program, the recording medium comprising switching instructions for switching between a normal mode in which a needle bar having a sewing needle attached to a lower end of the needle bar, is driven in an up and down direction to form stitches and a practice mode in which a sewing machine is operated in a condition where at least the needle bar is not driven.
Exemplary embodiments of the invention will be described below in detail with reference to the accompanying drawings in which:
The following describes first through third embodiments of the present disclosure with reference to the drawings. First, the first embodiment is described below with reference to
As shown in
The pillar 12 may be equipped with a card slot 35 on its right side surface in
Next, the configuration of the arm portion 13 is described. The arm portion 13 is mounted with an open-and-close cover 16 which is used to open and close an upper part of the arm portion 13. The open-and-close cover 16 is mounted along the longitudinal direction of the arm portion 13 and pivots about the upper rear part of the arm portion 13 so that it may be opened and closed around the right-and-left directional axis of the arm portion 13. When the open-and-close cover 16 is opened, the user can access a thread spool housing 17 formed in the vicinity of the midsection of the upper surface of the arm portion 13. The thread spool housing 17 is concaved to contain a thread spool 19 for supplying a thread to the sewing machine 1. On the inner wall surface of the thread spool housing 17 and to the side of the pillar 12, a thread spool pin 18 is disposed. The thread spool pin 18 protrudes toward the head portion 14. The thread spool 19 is attached to the thread spool pin 18. The thread spool 19 is attached to the thread spool pin 18 when the thread spool pin 18 is inserted through an insertion hole formed in the thread spool 19. A needle thread 20 extending from the thread spool 19 passes through a tensioner (not shown). A thread take-up spring (not shown) which is mounted on the head portion 14 may adjust a thread tension. Additionally, a plurality of thread hooking sections (not shown), such as a thread take-up lever etc. for taking up the needle thread by reciprocating in the up and down direction is supplied to the sewing needle 29 attached to a needle bar.
The arm portion 13 has a sewing machine drive shaft (not shown). The sewing machine drive shaft extends along the longitudinal direction of the arm portion 13 and is rotary-driven by a sewing machine motor 79 (see
A sewing start switch 21, a sewing stop switch 22, a needle up-and-down switch 23, a presser foot elevation switch 24, a reverse stitch switch 25, a speed control lever 70, and a mode transfer switch 28 are mounted at the lower part of the front surface of the head portion 14 and the arm portion 13. The sewing start switch 21 may initiate the start of sewing machine operation, i.e., the start of sewing. The sewing stop switch 22 may cause the sewing machine operation to stop, i.e., send an instruction to stop sewing. The needle up-and-down switch 23 may toggle the stop position of the sewing needle between an upper position and a lower position. The presser foot elevation switch 24 may raise and lower a presser foot 30. The reverse stitch switch 25 may feed a work cloth from the rear side to the front side, which is opposite to a normal direction. The speed control lever 70 may set the sewing speed. The mode transfer switch 28 may toggle between a practice mode and a normal mode, which will be described later.
Besides the above-described needle bar, thread take-up lever, tensioner, and the thread take-up spring, the head portion 14 may be equipped with an automatic thread hooking apparatus, an automatic threading mechanism, etc. (not shown. Behind the needle bar, a presser bar 31 may be disposed (see
An elevation mechanism 40 which raises and lowers the presser bar 31 is described below with reference to
The presser bar 31 is raised and lowered as driven by the presser foot elevation pulse motor 43 as follows. First, when the presser foot elevation pulse motor 43 is driven, its drive power is transmitted to the intermediate gear 45 and the pinion 46, thereby raising and lowering the rack formation member 41. If the rack formation member 41 is raised, the upper end surface of the rack formation member 41 butts against the retaining ring 42 fixed to the upper end of the presser bar 31, thereby raising the presser foot 30. Conversely, if the rack formation member 41 is lowered when the presser foot elevation pulse motor 43 is driven, the presser spring 48 is pressed downward and abuts the lower end of the rack formation member 41. In turn, the presser bar guide bracket 47 fixed to the presser bar 31 also is pressed downward, to press the presser foot 30 downward to such a lower position at which the presser foot 30 butts against the needle plate 33. Further, a potentiometer 52 (see
The elevation mechanism 40 may be equipped with a presser bar lifter lever 49. The presser bar lifter lever 49 may raise and lower the presser bar 31 by manual motion, independently of the operations to raise and lower the presser bar 31 by the presser bar elevation pulse motor 43. The presser bar lifter lever 49 has one end supported by a pivot pin 50 such that the presser bar lifter lever 49 is fixed to the sewing machine frame in such a manner that it is allowed to swing. The other end of the presser bar lifter lever 49 is fitted with an operation lever 51 for manual operations. If the operation lever 51 is operated manually to swing the presser bar lifter lever 49, the presser foot 30 is raisable from a lower position at which it butts against the needle plate 33 to an upper position which is higher than the needle plate 33 by a predetermined distance.
Next, the electrical configuration of the sewing machine 1 is described below with reference to
The CPU 61 may serve as a main control over the sewing machine 1 and performs operations and processing in accordance with a control program which may be stored in a control program storage region in the ROM 62. The RAM 63, which is a random access memory, may have as necessary, a sewing pattern data storage region to store data on pattern used for sewing, and a variety of storage regions to store the results of operations performed by the CPU 61. In the present embodiment, the RAM 63 may have a practice mode flag storage area 631 and a speed storage area 632. The practice mode flag storage area 631 may store a value that indicates whether the sewing machine is in the practice mode. Specifically, “1” stored in the practice mode flag storage area 631 indicates that the practice mode flag is “ON”, that is, the sewing machine is in the practice mode. On the other hand, “0” stored in the practice mode flag storage area 631 indicates that the practice mode flag is “OFF”, that is, the sewing machine is not in the practice mode, but rather is in the normal mode. The practice mode flag is switched each time the mode transfer switch 28 is operated (pressed). The speed storage area 632 may store a speed which is set by the speed control lever 70. The speed control lever 70 can be moved in the right and left direction to thereby control a sewing speed.
The following describes further operations of the sewing machine 1 described above. When the power is supplied to the sewing machine 1, the control program stored in the ROM 62 is performed by the CPU 61, and thereby starts the main processing.
As shown in
If is the power supply switch 27 is not instructed to turn OFF the power supply (NO at S2), in step 3 (S3) it is determined whether the mode transfer switch 28 is operated (S3). If the mode transfer switch 28 is operated (YES at S3), in step 7 (S7) it is determined whether the sewing machine is currently in the “practice mode” based on whether the practice mode flag is ON (S7). If the practice mode flag is ON to indicate that the sewing machine is in the “practice mode” (YES at S7), “0” is stored as the practice mode flag and the practice mode flag in step 9 (S9) is set as OFF to enter the “normal mode.” On the other hand, if the practice mode flag is OFF to indicate that the sewing machine is in the “normal mode” (NO at S7), in (S8) “1” is stored as the practice mode flag, and the practice mode flag is set as ON to enter the “practice mode.” In such a manner, the mode transfer switch 28 is operated to switch between the practice mode and the normal mode. Then, the process may return to S2.
Further, if the mode transfer switch 28 is not operated (NO at S3), in step 4 (S4) it is determined whether the sewing start switch 21 is operated. If the sewing start switch 21 is operated (YES at S4), in step 6 (S6) the sewing processing is performed to start the operation of the sewing machine 1 (see
In the first embodiment, instead of moving the sewing needle 29 up and down during actual sewing, the presser foot 30 is driven up and down. As shown in
On the other hand, in the sewing processing of
In such a manner, in the sewing machine 1 in the present embodiment, the user can appropriately switch between the “normal mode” and the “practice mode” in order to match the desired type of sewing. In the “normal mode”, normal sewing is performed to drive the needle bar in the up and down direction so that stitches may be formed. In the “practice mode”, the sewing machine can be operated in a condition where at least the needle bar is not driven. Specifically, instead of driving the sewing needle 29 independently of the sewing machine motor, the CPU 61 controls the elevation mechanism 40 that drives the presser foot 30 or the presser bar 31 in the up and down direction. Accordingly, in the “practice mode”, because the needle bar is not driven, the sewing needle 29 is not used so that just the presser foot 30 is driven in the up and down direction. Therefore, the work cloth is not damaged because the sewing needle does not make a hole in the work cloth. Furthermore, sewing practice can be repeated because no thread is required for this mode. Moreover, the presser foot 30 is driven in the up and down direction instead of the needle bar, so that the user can practice sewing with much the same feeling as if the needle bar is actually being driven in the normal sewing mode.
Further, in the practice sewing control processing, without changing the rotary-driving speed of the presser foot elevation pulse motor 43, the duration of the wait processing may be changed corresponding to a sewing speed which is set with the speed control lever 70. For example, if the sewing speed in actual sewing is set to 300 stitches per minute, it takes 0.2 seconds for each stitch to be formed by the sewing needle 29 (each vertical reciprocation of the needle bar). Further, if it takes, for example, 0.05 seconds each for the elevation mechanism 40 to raise and lower the presser foot 30, the wait lapse of time is 0.05 seconds (=0.1-0.05). The practice sewing control processing in this case is shown in
In such a manner, the CPU 61, which adjusts the wait processing lapse of time, can control the speed at which the presser foot is driven in the up and down direction, so that the user can practice sewing by adjusting a driving speed to a level suitable for his/her skills. Further, by appropriately controlling the driving speed when moving or rotating the work cloth in a desired direction, the user can practice sewing with much the same feeling as if he/she is controlling the vertical driving speed of the needle bar in actual sewing, i.e., the rotary speed of the sewing machine drive shaft, which is rotary-driven by the sewing machine motor.
Next, the second embodiment is described with reference to
The configuration of the ink recorder 90 fitted to a head portion 14 is described below with reference to
Between the compartment 93 and the ink cartridge 91, there is disposed a cartridge-side conduit (not shown) which is comprised of a flexible tube. The cartridge-side conduit has one end thereof connected to the bottom of the ink cartridge 91 and the other end thereof connected to the upper part of the compartment 93. Along the cartridge-side conduit, a cartridge-side conduit open-and-close electromagnetic valve 97 (see
Behind a presser bar 31, the ink ejection head 95 is held by an ejection head holder 96. The ink ejection head 95 is cylindrical in shape, has an opening at its lower end and ejects the ink charged in the compartment 93. The ejection head holder 96 is fixed to the presser bar 31. Between the ink ejection head 95 and the compartment 93, there is disposed a head-side conduit 94 which is comprised of a flexible tube. The head-side conduit 94 has one end thereof connected to the bottom of the compartment 93 and the other end thereof connected to the upper part of the ink ejection head 95. At the connection between the head-side conduit 94 and the bottom of the compartment 93, a head-side conduit open-and-close electromagnetic valve 98 (see
Next, the electrical configuration of the sewing machine 100 is described below with reference to
In the sewing machine 100 of the second embodiment, the above-described sewing start switch 21, sewing stop switch 22, needle up and down switch 23, presser foot elevation switch 24, reverse stitch switch 25, touch panel 26, potentiometer 52, and speed control lever 70, as well as a cartridge-side conduit open-and-close electromagnetic valve 97 and the head-side conduit open-and-close electromagnetic valve 98 are connected to an input interface 65. The cartridge-side conduit open-and-close electromagnetic valve 97 may control the amount of ink which is supplied from the ink cartridge 91 to the compartment 93. The head-side conduit open-and-close electromagnetic valve 98 may control the amount of ink which is supplied from the compartment 93 to the ink ejection head 95.
Next, the operations of the sewing machine 100 in the second embodiment are described below with reference to the flowcharts of
This processing is performed if the sewing start switch 21 is operated in the “practice mode”. As shown in
In such a manner, in the sewing machine 100 in the second embodiment, when the sewing machine 100 is in the practice mode, the sewing needle 29 does not operate because the sewing needle 29 can be driven by the sewing machine motor independently. Additionally, instead of driving the sewing needle 29, the ink recorder 90 causes ink to be ejected to the same position on the work cloth as the position at which a needle drop hole is formed through which the sewing needle pierces the work cloth as the needle bar is driven in the up and down direction, thereby generating a predetermined mark on the work cloth. Therefore, the user can confirm a trajectory (marks) of the ink ejected to the work cloth in place of stitches which would be formed when the sewing needle 29 is actually driven in actual sewing. Also, the user can confirm the results of his/her practice. Further, since the sewing needle 29 is not driven, the work cloth 99 will not be damaged. Moreover, since a thread is not used in this case, the thread can be conserved. The user can practice repeatedly by employing ink that can be erased with water, heat, etc. The user can also practice changing the ink ejection lapse of time to change the shape of the mark, and practice changing the color of the ink. If the marked trajectory is preferable, actual sewing can be performed along that trajectory.
Next, a third embodiment is described below with reference to
First, the marker recorder 200 is described below. As shown in
Next, the operations of the sewing machine 1 in the third embodiment are described below with reference to the flowcharts of
This practice sewing control processing is performed if a sewing start switch 21 is operated in the “practice mode”. As shown in
It is to be noted that, at S51, the marker recorder 200 is lowered by driving a presser foot elevation pulse motor 43 in such a manner that lowers a rack formation member 41 in an elevation mechanism 40, which raises and lowers the presser bar 31. At S53 the marker recorder 200 is raised by driving the presser foot elevation pulse motor 43 in such a manner that raises the rack formation member 41 in the elevation mechanism 40, which raises and lowers the presser bar 31. During a lapse of time when the marker recorder 200 is at a lowered position, the pen point 202 of the marker 201 stays in contact with the work cloth to perform recording.
Further, the wait lapses of time at S52 and S53 are determined so as to correspond to a sewing speed which is set with a speed control lever 70. For example, if the sewing speed in actual sewing is set to 300 stitches per minute, it takes 0.2 seconds for each stitch of the sewing needle 29 (each vertical reciprocation of a needle bar) to be formed. Further, if it takes, for example, 0.05 seconds each for the elevation mechanism 40 to raise and lower the presser foot 30, the wait lapse of time is 0.05 seconds (=0.1-0.05).
As can be seen, the sewing machine of the third embodiment is equipped with the marker recorder 200 instead of the presser foot 30. In the “practice mode”, instead of the presser foot 30 the marker recorder 200 that is equipped with the marker 201 moves independently of the sewing machine up and down. In a condition where the marker recorder 200 is at a lower position, the marker 201 comes in contact with the work cloth 99, and the needle bar is driven in the up and down direction to give a predetermined mark to the same position on the work cloth as the position at which a needle drop hole would be formed through which the sewing needle would pierce the work cloth. It is thus possible to confirm a trajectory of ink, instead of stitches which are formed when the sewing needle 29 is driven during actual sewing. Additionally, the results of practice can be confirmed. Further, since the sewing needle 29 is not driven, the work cloth 99 will not be pierced or damaged. Moreover, because a thread is not used in this case, the thread can be conserved. The user can practice repeatedly by employing ink that can be erased with water, heat, etc. The user can also practice changing the ink ejection lapse of time to change the shape of the mark, and practice changing the color of the ink. If a marked trajectory is preferable, sewing can be performed actually along that trajectory.
It is to be noted that the sewing machine of the present disclosure is not limited to the above-described embodiments and, of course, can be modified variously without departing from the spirit of the present disclosure. The above embodiments have the sewing start switch 21 to initiate the start of sewing and the sewing stop switch 22 to stop sewing. The embodiments have the speed control lever 70 to adjust a sewing speed. However, the start/stop of sewing and the setting of a sewing speed may be controlled by using a known foot controller 85, such as shown in
As shown in
In a case where the foot controller 85 is connected to the sewing machine 1, 100, or 300, at S4 in the main processing shown in
Number | Date | Country | Kind |
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2007-040326 | Feb 2007 | JP | national |
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4129084 | Kihara | Dec 1978 | A |
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A-46-1137 | Jan 1971 | JP |
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Number | Date | Country | |
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20080196646 A1 | Aug 2008 | US |