The present invention relates to an embroidery apparatus to be mounted on a sewing machine that is switchable between embroidery stitching and standard stitching, and more specifically, relates to an embroidery apparatus in which a carriage unit (Y-direction translation mechanism) with an embroidery frame mounted thereon can be evacuated during standard stitching.
A sewing machine accompanied by an embroidery apparatus is known. This type of the sewing machine is capable of both standard and embroidery stitching and is configured such that an embroidery frame is detachably mounted on the sewing machine to enable embroidery stitching of various patterns. In the case of performing standard stitching using the embroidery apparatus mounted on the sewing machine that is switchable between standard stitching and embroidery stitching, it is sometimes necessary to detach the embroidery apparatus from the sewing machine or detach a carriage unit with the embroidery frame mounted thereon from the embroidery apparatus.
A known embroidery apparatus (see Japanese Patent No. 4330728), which is used with a sewing machine switchable between embroidery stitching and standard stitching, has a carriage A that is disposed on a work bed 2 during embroidery stitching and that moves an embroidery frame 19 in the X and Y directions. The carriage A is driven by a carriage driving unit B accommodated in the work bed 2. In standard stitching, the carriage A is slid to an end side of the work bed 2 and is laid down there for storage.
Another known embroidery apparatus (see Japanese Unexamined Patent Application Publication No. 2007-135663) includes a Y-direction drive mechanism 34 that has a carriage 52 on which an embroidery frame 28 is detachably mounted and that moves the carriage 52 in the Y direction that orthogonally intersects the X direction. The embroidery apparatus also includes a first switching mechanism 61 that switches the Y-direction drive mechanism 34 between a stitching position where the horizontally positioned Y-direction drive mechanism 34 is enabled to perform embroidery stitching near the upper surface of a main unit 31 and a standing position where the Y-direction drive mechanism 34 stands vertically. The embroidery apparatus further includes a second switching mechanism 65 that switches the Y-direction drive mechanism 34 between the standing position and a storage position where the Y-direction drive mechanism 34 is laid horizontally along the front side of the main unit 31. When the Y-direction drive mechanism 34 is switched to the storage position, the upper surface of the body cover 35 of the Y-direction drive mechanism 34 is substantially flush with the upper surface of the body cover of the main unit 31.
In the embroidery apparatus described in Japanese Patent No. 4330728, slit-like throughholes 2d are formed in the work bed 2, and carriage-laying-down arms 5b passes through the slit-like throughholes 2d to move the carriage A over the work bed 2 in the X direction. When the work bed 2 is used as an auxiliary table during standard stitching, a cloth to be stitched may enter a slit-like throughhole 2d and get caught therein.
In the embroidery apparatus described in Japanese Unexamined Patent Application Publication No. 2007-135663, when the stitching mode is changed from embroidery stitching to standard stitching, a Y-direction cover 33 accommodating the Y-direction drive mechanism 34 is automatically moved to a switching position. It is necessary, however, for a user to manually move the Y-direction drive mechanism 34 to the standing position or to the storage position, which takes time and is inconvenient. Moreover, a downward-pointing abutting pin 85 is fixed to a left end portion of a non-engagement plate 81, and the main unit 31 has a straight slit 31a that is formed in the right-left direction and through which the abutting pin 85 is movable in the right-left direction together with an engagement plate 80. Due to such an arrangement, when the main unit 31 is used as an auxiliary table during standard stitching, a cloth to be stitched may enter the straight slit 31a and get caught therein, as is the case for the embroidery apparatus of Japanese Patent No. 4330728.
Accordingly, it is an object to provide an embroidery apparatus that can be detachably mounted on a sewing machine switchable between embroidery stitching and standard stitching, that does not have a slit used for supporting a carriage unit on the upper surface of the main unit, and that can automatically store the carriage unit with an embroidery frame mounted thereon at a position outside the main unit during standard stitching.
According to an aspect of the invention, an embroidery apparatus includes a main unit to be detachably mounted on a bed section of a sewing machine, a first translation mechanism that moves an embroidery frame holder with an embroidery frame mounted thereon in a first direction, a second translation mechanism that moves the first translation mechanism along an upper surface of the main unit in a second direction that orthogonally intersects the first direction, and an elevator mechanism that is supported by the second translation mechanism at opposite sides of the main unit and that raises and lowers the first translation mechanism.
In the embroidery apparatus, the elevator mechanism may include a pair of hinge arms that are swingably supported by the second translation mechanism. The hinge arms are swingable so as to move closer to each other and away from each other, and the swing movement of the hinge arms raises and lowers the first translation mechanism horizontally. In addition, the first translation mechanism may have an elevator driving shaft that rotates with a rotation axis extending in the first direction, and a pair of first support seats that move in the first direction due to rotation of the elevator driving shaft. In addition, each of the hinge arms may have a first end portion pivotally supported by the second translation mechanism using a fulcrum shaft, and a second end portion pivotally connected to a corresponding one of the first support seats. Moreover, the elevator mechanism may have an elevator shaft that is rotatably supported by the second translation mechanism and configured to rotate forward and backward and thereby raise and lower the first translation mechanism. In addition, the elevator mechanism may have a drive unit that is disposed at the second translation mechanism and that rotates the elevator shaft and also may have a second support seat that supports the first translation mechanism using the elevator shaft so as to be able to raise and lower the first translation mechanism.
In the embroidery apparatus, upon receiving a storage instruction, the first translation mechanism may move the embroidery frame holder to an end of the first translation mechanism and issue a first storage-ready notification, and the second translation mechanism may move the first translation mechanism in the second direction to a position outside the main unit and issue a second storage-ready notification. In addition, upon receiving the first storage-ready notification and the second storage-ready notification, the elevator mechanism may lower the first translation mechanism until an upper surface of the first translation mechanism is flush with the upper surface of the main unit.
The embroidery apparatus configured as described above does not have a slit used for supporting the first translation mechanism on the upper surface of the main unit. This reduces the likelihood of a cloth to be stitched entering the slit when the upper surface of the main unit is used as the auxiliary table during standard stitching. In addition, when the stitching mode is switched from embroidery stitching to standard stitching, the first translation mechanism is automatically evacuated from the upper surface of the main unit and stored at a position outside the main unit. Moreover, the upper surface of the first translation mechanism is positioned so as to be flush with the upper surface of the main unit, which enables both the upper surface of the first translation mechanism and the upper surface of the main unit to be used as the auxiliary table.
An embroidery apparatus according to an embodiment of the present invention will be described with reference to the drawings pertaining to examples. In the perspective view of
In
In the sewing machine body A, as illustrated in
As illustrated in
As illustrated in
The X-drive motor 14 rotates an X-idler pulley 15 that moves the first drive belt 16 reciprocally, and the reciprocal movement of the first drive belt 16 moves the second drive belts 17 reciprocally. The first X-carriage guides 13 include respective X-belt fixation bases 18 that are fixed to the second drive belts 17. Accordingly, the first X-carriage guides 13 move along the first guide rails 12 due to the reciprocal movement of the second drive belts 17.
An X-sensor screen 20 is attached to a first X-carriage guide 13. A first X-sensor 21 for detecting a home position and a second X-sensor 22 for detecting a storage position are disposed on the base plate 11 along the course of movement of the X-sensor screen 20. The first X-sensor 21 and the second X-sensor 22 serve as reference positions when the carriage unit D containing the Y-direction translation mechanism 30 (to be described later) moves in the X direction. X-pulley mounting plates 19 are provided for adjustment of the tension of respective second drive belts 17.
As illustrated in
The Y-drive motor 35 rotates a Y-idler pulley 36 that moves a Y-drive belt 37 reciprocally. The Y-carriage guide 33 includes a Y-belt fixation base 38 that is fixed to the Y-drive belt 37. Accordingly, the Y-carriage guide 33 moves along the second guide rail 32 in the Y direction due to the reciprocal movement of the Y-drive belt 37.
A Y-sensor screen 40 is attached to the Y-carriage guide 33. A first Y-sensor 41 for detecting a home position and a second Y-sensor 42 for detecting a storage position are disposed on the Y-carriage base plate 31 along the course of movement of the Y-sensor screen 40. The first Y-sensor 41 and the second Y-sensor 42 serve as reference positions when the embroidery frame holder 34 moves in the Y direction. A Y-pulley mounting plate 39 is provided for adjustment of the tension of the Y-drive belt 37.
As illustrated in
The first elevator motor 53 is attached to a standing plate 31a that stands at the Y-carriage base plate 31 and that extends in the Y direction. A worm gear 55 is fixed to the revolving shaft of the first elevator motor 53. The worm gear 55 of the first elevator motor 53 engages a worm wheel 56 that is fixed to a central portion of the elevator driving shaft 54 that are rotatably supported by drive shaft supports 57. A pair of bushes 58 being in sliding contact with corresponding drive shaft supports 57 prevent the elevator driving shaft 54 from being displaced in the thrusting directions.
The elevator driving shaft 54 has male screw portions 54a foamed at both ends thereof. The opposite male screw portions 54a are threaded in the opposite directions. The male screw portions 54a engage the internal threads of respective drive bases 59 that are fixed to the corresponding first Y-carriage seats 52. The worm gear 55 of the first elevator motor 53 rotates the worm wheel 56 fixed to the elevator driving shaft 54 at a reduced rotation speed. Rotation of the elevator driving shaft 54 thrusts the drive bases 59 in opposite directions along the third guide rails 51, thereby moving the first Y-carriage seats 52 fixed to the drive bases 59 in the corresponding thrusting directions along the third guide rails 51.
An elevator sensor screen 60 is attached to a drive base 59. An elevator sensor 61 for detecting a lower position is disposed at the standing plate 31a of the Y-carriage base plate 31 along the course of movement of the elevator sensor screen 60. The elevator sensor 61 serves as the reference position when the drive base 59 moves downward. A guide tab 62 is fixed to a rear portion of the Y-carriage base plate 31 at the bottom surface thereof. The guide tab 62 is configured to slide along a guiding groove 67 of the main unit C, which will be described later.
Next, the connection between the first Y-carriage seats 52 of the elevator mechanism 50 and the first X-carriage guides 13 of the X-direction translation mechanism 10 is described below. As illustrated in
The abutting member 66 is a device having the following function. As illustrated in
A fixation portion of the Y-carriage support 63 to which each abutting member 66 is fixed is adjustable to change the height position of the abutting member 66. Accordingly, each of the right and left abutting members 66 is adjusted appropriately so that each abutting member 66 can abut a flat surface 13b of the corresponding first X-carriage guide 13 at an appropriate position, which thereby enables the carriage unit D to be stably fixed to the Y-carriage support 63.
Moreover, as illustrated in
Next, operation and advantageous effects of the present example will be described. In the case of the embroidery apparatus B starting embroidery stitching, as illustrated in
The first X-carriage guides 13 are fixed to respective second drive belts 17 that are reciprocally moved by the reciprocal movement of the first drive belt 16 driven by the X-drive motor 14. The first X-carriage guides 13 are thereby movable along the first guide rails 12 in the X direction. When the carriage unit D is at the home position as illustrated in
Similarly, as illustrated in
Next, an operation for switching to standard stitching after the embroidery stitching is completed is described as follows. When the embroidery stitching is completed, the carriage unit D automatically returns to the home position illustrated in
Upon receiving the storage instruction, the embroidery apparatus B starts the Y-drive motor 35 of the Y-direction translation mechanism 30 disposed in the carriage unit D, which causes the Y-carriage guide 33 with the embroidery frame holder 34 mounted thereon to move rearward. As illustrated in
Simultaneously, the embroidery apparatus B starts the X-drive motor 14 of the X-direction translation mechanism 10 disposed in the main unit C, which moves the first X-carriage guides 13 leftward. As illustrated in
The embroidery apparatus B issues a first storage-ready notification when the Y-sensor screen 40 attached to the Y-carriage guide 33 of the Y-direction translation mechanism 30 masks the second Y-sensor 42 for detecting the storage position. The embroidery apparatus B issues a second storage-ready notification when the X-sensor screen 20 attached to the first X-carriage guide 13 of the X-direction translation mechanism 10 masks the second X-sensor 22 for detecting the storage position.
Upon receiving the first storage-ready notification and the second storage-ready notification, the elevator mechanism 50 starts the first elevator motor 53 to rotate the elevator driving shaft 54. The elevator driving shaft 54 is screwed into the drive bases 59 that are fixed to respective first Y-carriage seats 52. The rotation of the elevator driving shaft 54 moves the first Y-carriage seats 52 along the carriage unit D in opposite directions, in other words, in directions away from each other. Each first Y-carriage seat 52 is pivotally connected to the second end (pivot engagement portion 63b) of the corresponding Y-carriage support 63 using the pivot 65, and the first end (fulcrum engagement portion 63a) of the Y-carriage support 63 is pivotally connected to the corresponding first X-carriage guide 13 using fulcrum shaft 64. When the first Y-carriage seats 52 move toward the opposite ends of the carriage unit D, each Y-carriage support 63 turns outward while pivoting on the first end (fulcrum engagement portion 63a) so as to increase the distance between the second ends (pivot engagement portions 63b) of respective Y-carriage supports 63. This causes the carriage unit D to descend with the guide tab 62 of the carriage unit D sliding along the guiding groove 67 formed at the left surface of the main unit C.
As illustrated in
Next, an operation for switching to the embroidery stitching after the standard stitching is completed is described as follows. When the user returns to the embroidery stitching from the standard stitching, the user touches a switching button for switching to the embroidery stitching, which is displayed at the display 6 of the sewing machine body A, the control device in the sewing machine body A issues a returning-to-home-position instruction to the embroidery apparatus B upon receiving the request of switching to the embroidery stitching from the switching button.
Upon receiving the returning-to-home-position instruction, the embroidery apparatus B starts the first elevator motor 53 of the elevator mechanism 50 to rotate the elevator driving shaft 54. The elevator driving shaft 54 is screwed into the drive bases 59 that are fixed to the first Y-carriage seats 52. Rotation of the elevator driving shaft 54 moves the first Y-carriage seats 52 closer to each other toward the center of the carriage unit D. Each first Y-carriage seat 52 is pivotally connected to the second end (pivot engagement portion 63b) of the corresponding Y-carriage support 63 using the pivot 65, and the first end (fulcrum engagement portion 63a) of the Y-carriage support 63 is pivotally connected to the corresponding first X-carriage guide 13 using fulcrum shaft 64. When the first Y-carriage seats 52 move toward the center of the carriage unit D, each Y-carriage support 63 turns inward while pivoting on the first end (fulcrum engagement portion 63a) so as to decrease the distance between the second ends (pivot engagement portions 63b) of respective Y-carriage supports 63. The carriage unit D thereby ascends with the guide tab 62 of the carriage unit D sliding along the guiding groove 67 of the main unit C.
As illustrated in
Upon receiving the return-preparation completion notification, the embroidery apparatus B starts the Y-drive motor 35 of the Y-direction translation mechanism 30 disposed in the carriage unit D, which causes the Y-carriage guide 33 with the embroidery frame holder 34 attached thereto to move frontward. As illustrated in
Simultaneously, the embroidery apparatus B starts the X-drive motor 14 of the X-direction translation mechanism 10 disposed in the main unit C, which moves the first X-carriage guides 13 rightward. As illustrated in
As described above, the embroidery apparatus B of the present example is able to execute the switching operation automatically from the embroidery stitching to the standard stitching and also from the standard stitching to the embroidery stitching. In addition, in the embroidery apparatus B, the carriage unit D is supported by the elevator mechanism 50 at the sides of the main unit C. This enables the upper surface 8a of the body cover 8 of the main unit C and the upper surface of the carriage cover 29 of the carriage unit D to be used as the auxiliary table during the standard stitching.
Next, a second example will be described. In the second example, the structure of the elevator mechanism 50 of the first example is changed. In the present example, the same elements as those described in the first example will be denoted by the same reference symbols. Description of the second example is directed to differences from the first example, while duplicated description is omitted.
In
As illustrated in
The Y-direction translation mechanism 30 is disposed on the Y-carriage base plate 31. The Y-direction translation mechanism 30 includes the second guide rail 32, the Y-carriage guide 33, and the Y-drive motor 35. The second guide rail 32 extends in the Y direction, and the Y-carriage guide 33 is mounted on the second guide rail 32 and slides the embroidery frame holder 34 along in the Y direction. The Y-drive motor 35 drives the Y-carriage guide 33 using the Y-drive belt 37. The Y-sensor screen 40 is attached to the Y-carriage guide 33. The first Y-sensor 41 for detecting the home position and the second I-sensor 42 for detecting the storage position are disposed on the Y-carriage base plate 31 along the course of movement of the Y-sensor screen 40.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
An elevator sensor screen 84 is attached to a second Y-carriage seat 71. An elevator sensor 85 for detecting an upper position is attached to a sensor mounting plate 86 disposed so as to stand at the base plate 11 along the course of movement of the elevator sensor screen 84. The elevator sensor 85 serves as the reference position when the second Y-carriage seat 71 reaches the upper position and the cam roller 74 reaches the horizontal groove at the upper dead end of the spiral groove 72a.
Next, operation and advantageous effects of the present example will be described. During embroidery stitching, the carriage unit D of the embroidery apparatus Ba is held by the elevator mechanism 70 over the main unit C. The hook 77a of the stopper 77 urged by the urging spring 78 engages each drive gear 76, which prevents the elevator shaft 72 from rotating unexpectedly and thereby prevents the carriage unit D from descending. When the embroidery stitching is completed, the carriage unit D automatically returns to the home position illustrated in
Upon receiving the storage instruction, the embroidery apparatus Ba starts the Y-drive motor 35 of the Y-direction translation mechanism 30, which causes the Y-carriage guide 33 having the embroidery frame holder 34 to move rearward. The Y-sensor screen 40 attached to the Y-carriage guide 33 subsequently masks the second Y-sensor 42 for detecting the storage position. As a result, the I-drive motor 35 stops moving the Y-carriage guide 33 rearward, and the Y-direction translation mechanism 30 holds the embroidery frame holder 34 at the storage position outside the main unit C.
Simultaneously, the embroidery apparatus Ba starts the X-drive motor 14 of the X-direction translation mechanism 10, which moves the second X-carriage guides 23 leftward. The X-sensor screen 20 attached to the corresponding second X-carriage guide 23 subsequently masks the second X-sensor 22 for detecting the storage position. As a result, the X-drive motor 14 stops moving the second X-carriage guides 23 leftward, and the X-direction translation mechanism 10 and the elevator mechanism 70 holds the Y-direction translation mechanism 30 at the storage position outside the main unit C.
When the embroidery apparatus Ba causes the X-direction translation mechanism 10 to move the carriage unit D to the storage position, the drive gear 76 of each elevator shaft 72 of the elevator mechanism 70 engages the corresponding elevator gear 79. Simultaneously, the disengagement tab 77b of each stopper 77 abuts the corresponding disengagement-tab-abutting member 28 disposed on the base plate 11, which enables the elevator gear 79 to rotate.
The embroidery apparatus Ba issues the first storage-ready notification when the Y-sensor screen 40 attached to the Y-carriage guide 33 of the Y-direction translation mechanism 30 masks the second Y-sensor 42 for detecting the storage position. The embroidery apparatus B issues the second storage-ready notification when the second X-sensor 22 for detecting the storage position of the second X-carriage guides 23 of the X-direction translation mechanism 10 is masked.
Upon receiving the first storage-ready notification and the second storage-ready notification, the elevator mechanism 70 starts the second elevator motor 80 to rotate each elevator gear 79 using the elevator driving belt 81. Each elevator gear 79 engages the drive gear 76 and rotates the corresponding elevator shaft 72, which causes the each second Y-carriage seat 71 to descend. Rotation of each elevator shaft 72 lowers the cam roller 74 that engages the spiral groove 72a of the elevator shaft 72, which causes the corresponding second Y-carriage seat 71 to descend together with the cam roller 74.
When the second Y-carriage seats 71 descend, the number of rotation of each elevator shaft 72 is counted to the lower position from the upper position that has been detected by the elevator sensor 85 for detecting the upper position. The number counted is compared with a predetermined number of rotation of the elevator shaft 72. When the number counted reaches the predetermined number, the second elevator motor 80 stops rotating the elevator gear 79. Each second Y-carriage seat 71 reaches the lower position, and the cam roller 74 reaches the horizontal groove formed at the lower dead end of the spiral groove 72a. Consequently, the upper surface of the carriage unit D becomes flush with the upper surface of the body cover of the main unit C, as illustrated in
The operation for switching to the embroidery stitching after the standard stitching is completed is the same as that described in the first example, and detailed description will be omitted. In short, the elevator mechanism 70 raises the carriage unit D to the upper position, and subsequently the X-direction translation mechanism 10 and the Y-direction translation mechanism 30 move the carriage unit D to the home position. In the present example, the elevator mechanism 70 includes the stopper 77 to engage the drive gear 76 of each elevator shaft 72, which prevents the elevator shaft 72 from rotating unexpectedly. In addition, the grooves at the upper and lower dead ends of the spiral groove 72a of each elevator shaft 72 are formed horizontally. This prevents the carriage unit D from descending due to its own load when the drive gear 76 of the elevator shaft 72 is not connected to the external power.
As described above, the embroidery apparatus Ba of the present example is able to execute the switching operation automatically from the embroidery stitching to the standard stitching and also from the standard stitching to the embroidery stitching. In addition, in the embroidery apparatus Ba, the carriage unit D is raised and lowered by the rotation of the elevator shafts 72 of the elevator mechanism 70 at the sides of the main unit C. This enables the upper surface of the main unit C and the upper surface of the carriage unit D to be used as the auxiliary table during the standard stitching.
The embroidery apparatus of the present invention is advantageous. The embroidery apparatus can be applied to sewing machines capable of both embroidery and standard stitching. When the stitching mode is switched from embroidery stitching to standard stitching, the first translation mechanism is automatically evacuated from the upper surface of the main unit and stored at a position outside the main unit. Subsequently, the upper surface of the first translation mechanism is positioned so as to be flush with the upper surface of the main unit, which enables both the upper surface of the first translation mechanism and the upper surface of the main unit to be used as the auxiliary table.
Number | Date | Country | Kind |
---|---|---|---|
JP2020-101641 | Jun 2020 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5040476 | Takenoya | Aug 1991 | A |
5284104 | Hori | Feb 1994 | A |
5666894 | Jonsson | Sep 1997 | A |
6158365 | Hidechika | Dec 2000 | A |
6293212 | Ebata | Sep 2001 | B1 |
8051787 | Hidechika | Nov 2011 | B2 |
20070119354 | Ukai | May 2007 | A1 |
20070204779 | Naka | Sep 2007 | A1 |
20120060732 | Viltrakis | Mar 2012 | A1 |
20180320301 | Kawaguchi | Nov 2018 | A1 |
20220098775 | Osamura | Mar 2022 | A1 |
Number | Date | Country |
---|---|---|
2001-104672 | Apr 2001 | JP |
2007-135663 | Jun 2007 | JP |
4330728 | Sep 2009 | JP |
Number | Date | Country | |
---|---|---|---|
20210388551 A1 | Dec 2021 | US |