The present disclosure relates to a sewing machine capable of replacing a needle plate and a feed dog in accordance with a type of sewing and, in particular, relates to a sewing machine in which an operator is capable of mounting and dismounting the feed dog with a simple operation and in which the mounted or dismounted state of the feed dog and the type of the feed dog that has been mounted can be automatically identified.
A feeding mechanism of a sewing machine is known in which a piece of fabric that is pinched between a hold metal and a needle plate is fed by protruding and retracting (vertically moving) a feed dog through a long hole for the feed dog formed in the needle plate and by moving (horizontally moving) the feed dog in a front-rear direction. As illustrated in
However, since the feed dog is fixed to the feed bar at a portion below the needle plate, the needle plate needs to be dismounted each time the feed dog is replaced. Since the feed dog protrudes and retracts above the long hole for the feed dog formed in the needle plate, the gap between the long hole for the feed dog in the needle plate and the feed dog is designed to be small as possible to prevent the fabric from being dragged into the long hole for the feed dog in the needle plate. Accordingly, unless the feed dog is attached to the feed bar in an accurate manner, the feed dog may come into contact with the needle plate while the feed dog is in operation.
When the feed dog is replaced, the needle plate is first dismounted from the sewing machine, and after the replaced feed dog is temporally fixed to the feed bar, the needle plate is attached to the sewing machine once more. Subsequently, the fixing position of the feed dog is set by checking both the gap between the feed dog and the long hole for the feed dog in the needle plate, and the needle location in the needle hole, and the needle plate is dismounted without moving the feed dog. Finally, the fastening members of the feed dog are finally tightened so that the feed dog is fixed to the feed bar, the needle plate is attached once more, and the positional relationship between the needle plate and the feed dog is checked once more. If the position of the feed dog during final tightening is displaced, the needle plate needs to be dismounted once more and the adjustment of the feed dog needs to be redone. As described above, the operation of replacing the feed dog is very complex and needs much time and effort; accordingly, there is an issue in that the operator cannot easily carry out the operation of replacing the feed dog.
In order to overcome the above issues, Japanese Unexamined Patent Application Publication No. 2016-123772 (U.S. Patent Application Publication No. 2016/0194797, Description) discloses a conventionally known sewing machine including a feed bar applied with a motion in a feeding direction of the fabric, and a feed dog that feeds the fabric on the needle plate. The feed bar includes a mount portion on which the feed dog is mounted so as to be capable of being separated therefrom, and the feed dog includes a cam portion for mounting on the mount portion. The cam portion includes a flat first cam surface that comes in surface contact with a first receiving surface of the mount portion, a second cam surface that comes in line contact with a second receiving surface, and a third cam surface that is pressed by a pressing member. The surface contact between the first cam surface and the first receiving surface, and the line contact between the second cam surface and the second receiving surface are maintained by the pressing member, the feed dog is held by the feed bar in a suitable manner. The feed dog can be separated by pulling the feed dog against the pressing member in a direction opposite to the insertion direction, and replacement of the feed dog can be performed easily.
However, in the sewing machine described in Japanese Unexamined Patent Application Publication No. 2016-123772 (U.S. Patent Application Publication No. 2016/0194797, Description) described above, since the operator is not capable of easily checking whether the feed dog that has been replaced is a feed dog that matches the type of the sewing and whether the replaced feed dog is reliably mounted on the feed bar, there is an issue from the viewpoint of using the sewing machine safely.
An issue of the present disclosure is overcoming the above problem and an object of the present disclosure is to provide a sewing machine in which the operator can mount and dismount the feed dog with a simple operation and in which determination of whether the feed dog matches the selected type of the sewing and whether the feed dog is reliably mounted on the feed bar can be performed automatically by automatically identifying the feed dog that has been mounted by the replacement operation.
In order to overcome the issue described above, a sewing machine according to an aspect of the present disclosure employs a configuration in which the sewing machine is capable of replacing a feed dog in accordance with a type of sewing, the sewing machine including a feed bar performing a horizontal motion and a vertical motion by interlocking with a feeding mechanism, a feed dog detachably mounted on the feed bar, and a control unit that identifies the feed dog mounted on the feed bar. In the sewing machine, the feed dog includes an identification member that corresponds to a type of the feed dog, the feed bar includes a sensor member that detects the identification member and outputs an identification signal, and the control unit includes a feed dog identifying means that, based on the identification signal from the sensor member, identifies the type of the feed dog mounted on the feed bar.
An exemplary embodiment of the identification member and the sensor member according to the present disclosure employs a configuration in which the identification member includes a pressing portion formed on the feed dog, the sensor member includes a pressure sensor that detects pressing force of the pressing portion and that outputs a pressure-sensitive signal, and the control unit includes a feed dog mounted or dismounted determination means that, based on whether there is the pressure-sensitive signal from the pressure sensor, determines whether the feed dog is mounted or dismounted. Furthermore, a configuration is employed in which the pressing portion includes a projection that projects from an underside of the feed dog, and the feed bar includes, at a position opposing the projection, an attachment hole in which the pressure sensor is embedded.
A specific exemplary embodiment of the identification member and the sensor member according to the present disclosure employs a configuration in which the identification member includes a projection row in which at least one projection is arranged, and the sensor member includes a pressure sensor group that opposes the projection row, the pressure sensor group detecting whether there is the projection and outputting an identification signal corresponding to the projection row. Furthermore, a configuration is employed in which the control unit includes a feed dog mounted or dismounted determination means that, based on the identification signal from the pressure sensor group, determines whether the feed dog is mounted or dismounted. Further included is a sewing machine motor controller that controls the sewing machine motor and that starts or stops the sewing machine, in which the control unit includes a sewing machine stop commanding means that commands stoppage of the sewing machine to the sewing machine motor controller in a case in which the feed dog mounted or dismounted determination means determines that the feed dog is not mounted.
Moreover, a specific exemplary embodiment of the feed bar and a feed dog according to the present disclosure employs a configuration in which the feed bar incudes a feed bar base portion that is interlocked with the feeding mechanism, and a feed dog mount portion that is attached so as to be capable of being positioned with respect to the feed bar base portion, the sensor member being provided in the feed dog mount portion, and the feed dog includes an attaching portion that is detachably mounted on the feed dog mount portion, the identification member being provided in the attaching portion. Furthermore, a configuration is employed in which the feed dog mount portion includes a lifting spring that biases the attaching portion upwards, and a release lever countering biasing force of the lifting spring that presses and fixes the attaching portion to the feed dog mount portion. Moreover, an exemplary embodiment of the control unit according to the present disclosure employs a configuration in which the control unit includes a feed dog match determining means that determines whether the type of the feed dog identified by the feed dog identifying member matches the type of the sewing that has been selected. Furthermore, a configuration is employed in which the control unit includes an error indicating means that informs an operator in a case in which the feed dog match determining means determines that the type of the feed dog mounted on the feed bar does not match the type of the sewing that has been selected.
The sewing machine according to the present disclosure includes the feed bar performing the horizontal motion and the vertical motion by interlocking with the feeding mechanism, the feed dog detachably mounted on the feed bar, and the control unit that identifies the feed dog mounted on the feed bar, and in the sewing machine, the feed dog includes the identification member that corresponds to the type of the feed dog, the feed bar includes the sensor that detects the identification member and outputs the identification signal, and the control unit includes the feed dog identifying means that, based on the identification signal from the sensor member, identifies the type of the feed dog mounted on the feed bar; accordingly, an operator is capable of replacing the feed dog in a detachable manner with a simple operation and the feed dog that has been mounted by the replacement operation can be automatically identified. Moreover, since the type of the feed dog that has been mounted by the replacement operation can be identified, determination of whether the type of the identified feed dog matches the type of the selected sewing is automatically performed, and an error can be notified to the operator when the types are determined to not match each other.
Furthermore, in the sewing machine according to the present disclosure, the identification member includes the pressing portion formed on the feed dog, the sensor member includes the pressure sensor that detects the pressing force of the pressing portion and that outputs the pressure-sensitive signal, and the control unit includes the feed dog mounted or dismounted determination means that, based on whether there is the pressure-sensitive signal from the pressure sensor, determines whether the feed dog is mounted or dismounted; accordingly, not only determination of whether the feed dog is reliably mounted on the feed bar can be performed but also, in a case in which the feed dog is, if by any chance, not mounted on the feed bar, a command to stop the sewing machine is issued to the sewing machine motor controller so that the sewing machine is not actuated, therefore, the sewing machine can be used safely.
A sewing machine of an exemplary embodiment of the present disclosure will be described next with reference to the drawings.
In the following description, the longitudinal direction of
A feeding mechanism A is accommodated inside the free arm portion 2, and a piece of fabric is fed by protrusion and retraction of a plurality of tooth rows 8 of a feed dog B from the long holes 5 for the feed dog of the needle plate 3. As illustrated in
The feed dog B is mounted on a feed bar C attached to a rear end portion of a feed rock shaft crank 13. A front end portion of the feed rock shaft crank 13 is rotatably supported by pivot pins 17 fixed to the arm portions 16 formed in an integrated manner with a feed rock shaft 15 that is supported about screw centers 14 fixed to the free arm portion 2 in a swingable manner. The feed rock shaft 15 is swung by a feed fork 18 that is fitted to the horizontal feed cam 11 secured to the lower shaft 10. The feed rock shaft crank 13 converts a swinging motion of the feed rock shaft 15 into a front-rear motion and transmits the motion to the feed dog B.
The feed bar C is attached to the rear end portion of the feed rock shaft crank 13 with a pivot shaft 19 in a swingable manner. The feed bar C following the vertical feed cam 12 secured to the lower shaft 10 is swung about the pivot shaft 19, and the feed dog B attached to the feed bar C is protruded and retracted through the long holes 5 for the feed dog of the needle plate 3.
As illustrated in
As illustrated in
A projection row En is provided on the underside 21b of the attaching portion 21. The projection row En is an identification member in which one to three projections E functioning as pressing portions are aligned so as to oppose a sensor group Dn of a feed dog mount portion C2 described later. In other words, the arrangement patterns of the projections E are changed in the projection row En so that the type of the feed dog B that has been mounted is identified.
As illustrated in
The feed bar base portion C1 includes a following portion 25 at a lower end of a leg portion 24 hanging downwards from the left side. The following portion 25 abuts against the vertical feed cam 12 (see
Steps are formed on the bottom surface of the feed dog mount portion C2 so as to correspond to the upper step surface 27a and the lower step surface 27b formed in the feed bar base portion C1. The feed dog mount portion C2 includes an upper surface 30 formed with an upper step surface 30a formed at a high position on the left side of the feed dog mount portion C2, and a lower step surface 30b formed at a position lower than that of the upper step surface 30a and on the right side of the feed dog mount portion C2. Fixing holes 32a and 32b that are screwed together with fixing screws 31a and 31b, respectively, are formed in predetermined positions in the upper step surface 30a and the lower step surface 30b, respectively.
In order to fit the attaching portion 21 of the feed dog B, the feed dog mount portion C2 is provided with a fitting recess 33 that extends to the right side and that is adjacent to the fixing hole 32a formed in the upper step surface 30a. As illustrated in
A spring recess 35 is formed in the right side of the bottom surface 33b. A lifting spring 37 that biases the attaching portion 21 of the feed dog B upwards is fixed to the spring recess 35 with a small fixing screw 36. Three attachment holes 38 are each formed in the bottom surface 33b at a position avoiding the spring recess 35 and in the up-down direction. Three pressure sensors D1, D2, and D3 that detect pressing force of the one to three projections E, which are provided on the underside 21b of the attaching portion 21 of the feed dog B and that function as pressing portions, are embedded in the attachment holes 38.
A pair of front rear bearing walls 40 are formed between the upper step surface 30a and the lower step surface 30b of the feed dog mount portion C2, and bearing holes 42 in which a rotating shaft 41 is inserted and that fix the rotating shaft 41 are provided in the bearing walls 40.
The release lever C3 includes a shaft portion 44 in which a shaft hole 43 into which the rotating shaft 41 is inserted is formed, and a lever plate 45 provided so as to extend rightwards from an upper portion of the shaft portion 44. The lever plate 45 is biased so as to be horizontal with respect to the upper step surface 30a of the feed dog mount portion C2 with repulsive force of a lever spring 46 wound around the rotating shaft 41 between the shaft portion 44 and the bearing walls 40.
A through hole 47 through which the fixing screw 31b penetrates is drilled in the lever plate 45 in the up-down direction. A locking portion 48 that abuts against the locking protruding piece 23 of the attaching portion 21 of the feed dog B is formed on a left end portion of the lever plate 45. As illustrated in
As illustrated in the block diagram in
A control unit 54 that identifies the feed dog B mounted on the feed bar C is provided in the sewing machine body. The control unit 54 includes a microcomputer including a CPU 55, a ROM 56, and a RAM 57, the input interface 58, and an output interface 59. The identification code receiver 51, a touch panel 52, and a start/stop switch 53 are connected to the input interface 58. A liquid crystal display 60 and a sewing machine motor controller 61 are connected to the output interface 59.
The liquid crystal display 60 provided in the sewing machine body includes the transparent touch panel 52 stacked on the front side thereof. Various work menus, function menus, and messages needed for the sewing work are displayed on the liquid crystal display 60 on which the transparent touch panel 52 is stacked, and by performing a touch operation on a “type of the sewing selection” display in the work menu, as described below, determination is made whether the mounted feed dog B matches the selected type of sewing, and the determination result is displayed on the liquid crystal display 60. Furthermore, the sewing machine motor controller 61 controls a sewing machine motor (not shown) upon operation of the start/stop switch 53, and starts or stops the sewing machine.
Use modes and effects of the present embodiment will be described. As illustrated in
In order to attach the feed dog mount portion C2 to the feed bar base portion C1, the feed dog mount portion C2 is placed on the upper surface 27 of the feed bar base portion C1 and, then, the fixing screw 31a is inserted into the fixing hole 32a of the feed dog mount portion C2 from above and is screwed to the fixing screw hole 28a of the feed bar base portion C1. In a similar manner, the fixing screw 31b is passed through the through hole 47 of the release lever C3, is inserted into the fixing hole 32b of the feed dog mount portion C2, and is, further, screwed into the fixing screw hole 28b of the feed bar base portion C1. As described above, the feed dog mount portion C2 can be positioned and fixed to the feed bar base portion C1 by being screwed with the fixing screws 31a and 31b. The feed bar C assembled in the above described manner is set to the feeding mechanism A.
As illustrated in
Subsequently, at the same time as when the abutment between the oblique underside 23a of the locking protruding piece 23 of the attaching portion 21 and the oblique upper surface 48a of the locking portion 48 of the release lever C3 is released, as illustrated in
As described above, the feed dog B is fixed and mounted on the feed dog mount portion C2 by fitting the insertion pieces 22 on the left side of the attaching portion 21 and the insertion receiving portions 34 on the left side of the fitting recess 33 to each other, by fitting the locking protruding piece 23 on the right side of the attaching portion 21 and the locking portion 48 on the left side of the release lever C3 to each other, and, further, by abutting the front and rear lateral sides 21a of the attaching portion 21 and the front and rear lateral sides 33a of the fitting recess 33 to each other.
To detach the feed dog B from the feed bar C, as illustrated in
Regarding the feed dog B and the feed bar C of the present exemplary embodiment, the feed dog B can be mounted on the feed dog mount portion C2 of the feed bar C easily, and the feed dog B can be dismounted easily by pressing down the release lever C3 of the feed bar C; accordingly, a feed dog B optimum for the material and thickness of the stitched fabric and for the type of the sewing can be mounted on the feed dog mount portion C2 by having a plurality of types of feed dog B, including feed dog portions 20 having tooth rows 8 with different heights and arrangement patterns, be readily available.
In the feed dog mount portion C2, the three pressure sensors D1, D2, and D3 are provided on the bottom surface 33b of the fitting recess 33, and in the feed dog B, one to three projections E that function as a pressing portion opposing the pressure sensors D are provided on the underside 21b of the attaching portion 21 so that, as in the flow chart illustrated in
In the present exemplary embodiment, the sensor group Dn includes three pressure sensors D1, D2, and D3 on the bottom surface 33b of the fitting recess 33, and the projection row En provided on the underside 21b of the attaching portion 21 formed on the feed dog B includes one to three projections E that oppose the three pressure sensors D1, D2, and D3. Regarding the arrangement pattern of the one to three projections E constituting the projection row En, assuming that “1” denotes a case in which there is a projection E and “0” denotes a case in which there is no projection E, when the identification code expressing the existence of a projection E is expressed in the order of projections E3, E2, and E1, there will be seven identification codes, namely, “001”, “010”, “011”, “100”, “101”, “110”, and “111”.
As in the present exemplary embodiment, in a case in which the sensor group Dn is provided with three pressure sensors D1, D2, and D3, projection rows En that have seven arrangement patterns can be identified; accordingly, at the most, seven feed dogs B that each have tooth rows 8 in which the tooth height and the arrangement pattern have been changed, can be identified. Note that in the present exemplary embodiment, while the number of pressure sensors D provided on the bottom surface 33b of the fitting recess 33 is three, the number of pressure sensors D can be n, and the maximum number of projections E can be n as well so as to match the number of pressure sensors D. In such a case, the number of arrangement patterns of the projection E is, at the most, (n-th power of 2)-1.
Furthermore, other than the projection row En for identifying the mounted feed dog B, a projection (not shown) serving as a pressing portion dedicated for detection of whether the feed dog B is mounted or dismounted can be provided, and a pressure sensor (not shown) dedicated for detection of whether the feed dog B is mounted or dismounted can be provided on the feed dog mount portion C2. In such a case, “000” can be used as the identification code of the arrangement pattern of the projection E of the feed dog B.
A manner in which the control unit 54 identifies the type of the mounted feed dog B when an operator mounts the feed dog B on the feed dog mount portion C2 as illustrated in the block diagram in
First, since the operator views the “type of the sewing selection” display in the work menu displayed on the liquid crystal display 60 and waits for the type of the sewing to be selected on the transparent touch panel 52 stacked on the front side of the liquid crystal display 60, in determining “Has the type of the sewing been selected?” in step S1, “NO” is determined until the type of the sewing is selected, and the determination loop of step S1 is repeated until the type of the sewing is selected. Subsequently, in step S1, when the operator touches the touch panel 52 and the type of the sewing is selected, “YES” is determined, and the process proceeds to step S2.
Subsequently, in step S2, determination on “Is feed dog mounted?” is made. In the example in
Subsequently, receiving the determination result of step S2, in step S3, an alarm message “Please attach the feed dog” is indicated through the liquid crystal display 60 to notify the operator that the feed dog B is not mounted on the feed dog mount portion C2, and the process proceeds to step S4. Note that the indication of the alarm message is not limited to a display of characters on the liquid crystal display 60 and may be performed through a phonetic representation. Subsequently, in step S4, a sewing machine stop command is issued to the sewing machine motor controller 61 and the start/stop switch 53 is made inoperable so that the sewing machine motor is not actuated even when the operator operates the start/stop switch 53. The process is returned to step S2, and the determination loop including steps S2 to S4 is repeated until the feed dog B is mounted on the feed dog mount portion C2.
Subsequently, when the operator mounts the feed dog B on the feed dog mount portion C2, since in the example in
Subsequently, after the identification code from the identification code transmitter 50 is received with the identification code receiver 51 and the identification code “001” is input to the control unit 54, in step S5, the type of the mounted feed dog B (the mounted feed dog B for straight stitching, for example) is identified from the input identification code, and the process proceeds to step S6. Subsequently, in step S6, when determination on “Does the feed dog match the type of sewing?” is made, in a case in which, for example, the type of the feed dog B identified in step S5 had been the feed dog for straight stitching and the type of the sewing identified in step S1 had been a feed dog B for zigzag stitching, since the feed dog B does not match the type of sewing, “NO” is determined, and the process proceeds to step S7.
Subsequently, receiving the determination result in step S6, in step S7, an error message “Please change the feed dog to the feed dog B for zigzag stitching” is indicated on the liquid crystal display 60 to inform the operator that the mounted feed dog B does not match the selected type of stitching, and the process proceed to step S4. Note that the indication of the error message is not limited to a display of characters on the liquid crystal display 60 and may be performed through a phonetic representation. Subsequently, in step S4, the sewing machine stop command is issued to the sewing machine motor controller 61 and the start/stop switch 53 is made inoperable so that the sewing machine motor is not actuated even when the operator operates the start/stop switch 53. The process is returned to step S2, and the process including steps S2 to S6 is repeated until the feed dog B matches the type of sewing.
Subsequently, when the operator changes the feed dog B to the feed dog B for zigzag stitching, since the feed dog B matches the type of sewing, “YES” is determined in step S6, and the process proceeds to step S8. Finally, in step S8, when the operator operates the start/stop switch 53, the control unit 54 commands the sewing machine motor controller 61 to start the sewing machine motor, and the sewing machine performs the selected type of sewing. As it can be understood from the above description, in the flow chart in
As described above, by allowing the control unit 54 of the sewing machine to identify the type of the feed dog B mounted on the feed dog mount portion C2, sewing can be performed with the feed dog B that matches the selected type of the sewing mounted on the feed bar C. Furthermore, after identifying the feed dog B mounted on the feed bar C, the type of the sewing that matches the identified feed dog B may be displayed on the liquid crystal display 60.
In the present exemplary embodiment, while the feed dog B accommodated inside the free arm portion 2 of the bed portion 1 is changeable in a detachable manner; it goes without saying that the present disclosure is not limited to a sewing machine that includes a free arm portion such as the one described above and may be applied to sewing machines including various forms of bed portions.
The sewing machine of the present disclosure is capable of having the operator change the feed dog in a detachable manner with a simple operation, and is capable of automatically determining whether the feed dog matches the type of the sewing and whether the feed dog has been reliably mounted on the feed bar by automatically identifying the feed dog that has been mounted with the replacement work; accordingly, sewing can be performed after selecting the feed dog that matches the selected type of sewing, and the sewing machine can be widely applied to various sewing machines advantageously.
Number | Date | Country | Kind |
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2016-182015 | Sep 2016 | JP | national |