This application is based upon and claims the benefit of priority from the prior Japanese Patent Application 2009-079168, filed on, Mar. 27, 2009, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a multi-needle sewing machine provided with a needle-bar case transfer mechanism that transfers a needle-bar case relative to the body of the sewing machine and a first wiring and a second wiring extended across the needle-bar case and the body of the sewing machine.
Typical industrial sewing machines have been conventionally provided with a transfer element such as a holder for holding a workpiece cloth that is transferred relative to the body of the sewing machine. Such type of sewing machine requires wiring such as lead wires extending across the sewing machine body and the transfer element to be of a length that allows movement of the transfer element, meaning that some extra length needs to be obtained. In view of such play in the length, the wiring needs to be organized so that they do not interfere with the movement of the transfer element to eliminate the possibility of damaging and disconnections caused by the intermediate portions of the wiring being entangled with the components of the sewing machine.
To address such concerns, sewing machines have been provided with wiring organizers. For instance, such sewing machine is provided with a holder for holding a workpiece cloth spread out on a sewing machine table, and a couple of transfer mechanisms that transfer the holder in a first direction along a guide rail provided on the sewing machine table and a second direction orthogonal to the first direction, respectively. The wirings that connect components such as an actuator for activating the holder and control-related sections provided below the sewing machine base, or in the sewing machine body side, are drawn upward from the sewing machine base to be hung at their intermediate portions by a fastener. The fastener is provided in the form of a bar at one of the transfer mechanisms and has a hook-shaped placement at its tip. The wirings are placed on the placement of the fastener and tied to the bar shaped portion of the fastener by strings, for instance.
Since the wiring organizer allows play in the length of the wirings, the wirings hang down from time to time between the fastener and the holder, serving as the transfer element, by the movement of the transfer element. Because the intermediate portions of the wirings are placed on the hooked shaped placement of the fastener, there is a risk of the wirings being displaced from the placement and coming in contact with the components of the sewing machine.
The multi-needle sewing machine is typically provided with a needle-bar case, as described earlier, that supports a plurality of needle bars so as to be movable up and down. By transferring the needle-bar case relative to the sewing machine body, one of the needle bars is selectively switched to a position opposing a needle drop position of the needle bar. Thus, when extending the wiring or electrical cords across the sewing machine body and the needle-bar case, the wirings need to be organized so that they do not entangle with the components of the sewing machine even when the wirings slack by the movement of the needle-bar case.
One object of the present disclosure is to provide a multi-needle sewing machine that eliminates slacking of the wiring extending across the sewing machine body and the needle-bar case, and at the same time reliably preventing failures such as damaging and disconnections of the wirings.
In one aspect of the present disclosure, a multi-needle sewing machine provided with a sewing machine body includes a plurality of needle bars that each allow attachment of a sewing needle at a lower end thereof; a needle-bar case that supports the plurality of needle bars so as to be movable up and down; a needle-bar case transfer mechanism that selectively switches one of the plurality of needle bars to a needle drop position by transferring the needle-bar case relative to the sewing machine body; a first wiring and a second wiring that are each connected to an electrical component provided at the needle-bar case and that is extended across the sewing machine body and the needle-bar case; wherein the first and the second wiring are held such that the first wiring and the second wiring are separated in a direction of transfer of the needle-bar case and a first intermediate portion of the first wiring and a second intermediate portion of the second wiring are curved so as to either cross over or proximate one another to allow the first wiring and the second wiring to be moved relative to one another at the first intermediate portion and the second intermediate portion.
Other objects, features and advantages of the present disclosure will become clear upon reviewing the following description of the illustrative aspects with reference to the accompanying drawings, in which,
A first exemplary embodiment applying the present disclosure to a multi-needle embroidery sewing machine, hereinafter referred to as a multi-needle sewing machine M, will be described with reference to
Referring to
Feet 1, pillar 2, arm 3, and cylinder bed 4 are provided integrally with sewing machine body 7. Sewing machine body 7 is provided with components such as a controller not shown that are responsible for the overall control of multi-needle sewing machine M and control panel 6. On the upper surface of cylinder bed 4, needle plate 4a only shown in
Above feet 1, carriage 8 oriented in the left and right direction is disposed which contains an X-drive mechanism not shown that drives a frame mount base not shown provided in front of carriage 8 in the X direction or the left and right direction. Within the left and right feet 1, a Y-direction drive mechanism is provided that drives carriage 8 in the Y direction or the front and rear direction. The workpiece cloth not shown to be embroidered is held by a rectangular embroidery frame not shown which is mounted on the frame mount base. The embroidery frame being driven by the Y-direction drive mechanism and the X-direction drive mechanism is transferred in the Y direction in synchronism with carriage 8 or in the X direction along with the frame mount base, to allow the workpiece cloth to be fed.
Though not shown, above arm 3 of sewing machine body 7, a thread supplier is provided that has six thread pins each being mounted with a thread spool. On the front end of the arm 3, guide rail 9 is provided that extends in the left and right direction which slidably supports needle-bar case 5.
Next a description will be given on needle-bar case 5 and its peripheral structures with reference to
Needle-bar case 5 supports six vertically extending needle bars 10 that are arranged side by side in the left and right direction. Needle bars 10 are allowed to move up and down and each needle bar 10 has sewing needle 11 attached on its lower end. Needle-bar case 5 is further provided with six thread take-ups 12 that are associated with the six needle bars 10. Thread take-ups 12 are also allowed to move up and down. As indicated in double-dot chain line in
Needle-bar case 5 is generally reverse L-shaped in side view and is provided with roller mount plate 15 extending in the left and right direction on its upper rear end. Roller mount plate 15 has six roller shafts 17a associated with the six needle bars 10 that are spaced equally with the corresponding needle bars 10. Roller shafts 17a protrude in the front and rear direction and cylindrical roller 17b is provided rotatably behind each roller shaft 17a.
On the other hand, as shown in
When needle-bar case transfer motor 24 is driven in the normal or reverse direction, the rotational movement is transmitted to rotary shaft 21 by way of deceleration gear mechanism 23 to cause spiral cam 22 to rotate. As spiral cam 22 rotates, it travels across rollers 17b one by one through engagement with each roller 17b from the left to right or vice versa thus, transferring needle-bar case 5 leftward indicated by arrow D1 in
As can be seen in
Needle-bar case 5 is provided with electrical components, one example of which is a couple of lights 27a and 27b. Light 27a includes a rectangular cover 28 serving as an exterior housing and a light source not shown such as a chip LED (light emitting diode) not shown provided within cover 28. Chip LED is implemented on a substrate not shown within cover 28 and a connector not shown is provided on the substrate to which a lead wire hereinafter referred to as the first wiring 30 is connected for supplying electricity to the LED. Likewise, light 27b is provided with cover 28 and a chip LED which is implemented on a substrate within cover 28. The lead wire, hereinafter referred to as the second wiring is 31 is connected to the connector provided on the substrate on which LED is implemented. Light 27a and light 27b are mounted at the lower end left side and right side of needle-bar case 5, respectively to provide enough work space in the front side of components such as needle bar 10 and sewing needle 11 without interfering with needle threading or sewing needle 11 replacement work and at the same time providing sufficient lighting on the surface of the workpiece cloth.
The first and second wirings 30 and 31 are bendable and thus, run from the connector to the front and upper surfaces of needle-bar case 5 to extend over to arm 3 of sewing machine body 7 side to be connected to controller. The support structure of the first and the second wirings 30 and 31 will be described with reference to
Fastening elements are provided at both the needle-bar case side and the sewing machine body 7 side to separate the first wiring 30 and the second wiring 31 to the left and right. To elaborate, as show in
Wire fasteners 32a and 32b are identical to one another. As can be seen in
As can be seen in
Needle-bar case side fasteners 33a and 33b are mounted on the upper left and right sides of needle-bar case 5 by screws 43 inserted through screw holes 37b and 38b. First wiring 30 is lined along vertical section 37, insert groove 40a, projecting section 39, insert groove 40b, and horizontal section 38, curving from time to time, to be covered by needle-bar case side fastener 33a. Second wiring 31 is lined in the same route, curving from time to time, to be covered by needle-bar case side fastener 33b. Thus, first and second wirings 30 and 31 are fastened unmovably by needle-bar case side fasteners 33a and 33b, respectively. The rear end of horizontal sections 38 of needle-bar case side fasteners 33a and 33b, where ribs 41d are provided, define fastening sections 42a and 42b that are inclined rearwardly upward. Thus, the first and second wirings 30 and 31 maintain their relative positioning at the rear end or the stationary end of needle-bar case 5 even when needle-bar case 5 is moved.
Referring to
As can be seen in
Body side fastener 45 is attached to fixture frame 20 by screw 49 only shown in
The first and the second wirings 30 and 31, extending across sewing machine body 7 and needle-bar case 5, are crossed over each other so as to curve at their intermediate portions 30a and 31a.
As can be seen in
L1F+L1R=L2F+L2R (1)
As can be understood from above, the first and second wirings are configured to be equal in length between body side fasteners 45 and needle-bar case side fasteners 33a and 33b. Needle-bar case 5 is transferred between the rightmost position shown in
A description will be given hereinafter on the operation of the above described configuration.
As can be seen in
The change in the status of the first and second wirings 30 and 31 caused by the transfer of needle-bar case 5 will be described with reference to
Referring to
L1F+L1R=L2F+L2R=(A2+B2)1/2 (2)
In contrast, as shown in
L1R′=L2F′=[{(A+C)2+B2}1/2]½ (3)
L1F′=L2R′=[{(A−C)2+B2}1/2]½ (4)
According to the present exemplary embodiment, the imaginary quadrilateral formed when needle-bar case 5 is in the middle position is a trapezoid to be specific, however, it can be generally described as being substantially rectangular, and hence, the above described equations (1) to (4) stand. Thus, as shown in
According to multi-needle sewing machine M of the present exemplary embodiment, the first and second wirings 30 and 31 are disposed so as to be separated from each other in the direction of transfer of needle-bar case 5, and the intermediate portions 30a and 31a of the first and second wirings 30 and 31 are crossed over in a curve. This allows appropriate play in the lengths of the first and second wirings 30 and 31 required for the transfer of needle-bar case 5 while allowing the first and second wirings 30 and 31 to crossover with appropriate tension operated on each other. Thus, even if needle-bar case 5 is transferred, variation in the tension of the first and second wirings 30 and 31 can be restrained as much as possible while preventing slack by establishing a hold at intermediate portions 30a and 31a to reliably prevent damages and disconnection of the wirings.
The first and second wirings 30 and 31 have been disposed to crossover at the substantial center of an imaginary quadrilateral formed by connecting the couple of fastening sections 47a and 48a of body side fastener 45 and the couple of fastening sections 42a and 42b of needle bar side fasteners 33a and 33b. Thus, by disposing the first and second wirings 30 and 31 so as to reside within a given plane with appropriate tension operated between them, they can be reliably prevented from entangling with components of multi-needle sewing machine M such as needle-bar case transfer mechanism 25 even if needle-bar case 5 is transferred, as well as allowing the organization of the wirings to be as compact as possible. Further, the above described configuration allows the play in the lengths of the first and second wirings 30 and 31 to be equal while optimizing the play in the lengths to prevent the wirings 30 and 31 from interfering with the transfer of needle-bar case 5. Yet, further, the length between fasteners 42a and 47a of the first wiring 30 (L1F+L1R) and the length between fasteners 42b and 48a of the second wiring 31 (L2F+L2R), and the length of L1F to L2R′ of each segments of the first and the second wirings 30 and 31 can be obtained from equations (1) to (4). Still further, because the mutual distance of the four fasteners 42a to 48a, in other words, A and B, can be specified in anticipation of the minimum length L0 (=(B2+C2)½) required in transferring needle-bar case 5 from the rightmost position to the left most position, the first and second wirings 30 and 31 can be organized without excessive play in their lengths.
The first and second wirings 30 and 31 of the second exemplary embodiment are gathered by ring element 51 at their intermediate portions 30a and 31a. Ring element 51 is made of a synthetic resin material, for example, and is configured as an annular holding element having insert hole 52 allowing insertion of the first and second wirings 30 and 31. As shown in
According to the second exemplary embodiment, because the first and second wirings 30 and 31 are held at their intermediate portions 30a and 31a so as to be curved in close proximity to one another by ring element 51, they can be organized with appropriate tension operated on each other. Further, because the first and second wiring 30 and 31 are allowed to move relative to the other, they can be held by ring element 51 by preventing the variance in tension as much as possible without slacking even if needle-bar case 5 is transferred. Further, because the first and second wirings 30 and 31 are held in close proximity to one another without physical contact, no friction occurs between the wirings 30 and 31 to reliably prevent the wear of the wirings.
Further, the first and second wirings 30 and 31 are configured to reside within a given plane with appropriate tension operated between them. Thus, the play in the length of the first and second wirings 30 and 31 can be made equal etc., to provide the effects yielded by the first exemplary embodiment.
The holding element that holds the intermediate portions 30a and 31a of the first and second wirings 30 and 31 in a curved and proximate state is configured by ring element 51 that allows the first and second wiring 30 and 31 to be passed through it. This allows the holding element to be simplified as much as possible while establishing a reliable hold of intermediate portions 30a and 31a of the first and second wiring 30 and 31.
In the first exemplary embodiment, the first and second wirings 30 and 31 are placed on top of the other at cross over or curved section Po. In contrast, the second exemplary embodiment employs ring element 51 designed to reduce its height h to hold the first and second wirings 30 and 31 without physical contact. Thus, the vertical thickness of curved section Po can be reduced as compared to when the first and second wirings are crossed over.
The first and second wirings 30 and 31 of the third exemplary embodiment are held at their intermediate portions by 30a and 31a by holding element 53. Holding element 53 is provided with a couple of pulleys 54 and support element that rotatably supports pulleys 54. Pulleys 54 are disc shaped and have guide grooves 54a on their edges that are recessed radially inward in arc shape in front view as viewed in
As shown in
According to the third exemplary embodiment, when needle-bar case 5 is being moved, the sliding movement of the first and second wirings 30 and 31 relative to holding element 53 can be executed smoothly by pulleys 54. Further, because the first and second wirings are held at intermediate portions 30a and 31a that are gradually curved while reducing the friction between the first and second wirings 30 and 31, damaging and wear etc. of intermediate portions 30a and 31a of the first and second wirings 30 and 31 can be prevented. Further, because the first and second wirings 30 and 31 can be held by holding element 53 at the substantial center of the imaginary quadrilateral, the play in lengths of the first and second wirings 30 and 31 can be made equal etc., to obtain the effects provided in the second exemplary embodiment.
As described in the above first to third exemplary embodiments, the first and second wirings 30 and 31 are disposed so as to be separated from one another in the direction of transfer of needle-bar case 5, while crossing the intermediate portions 30a and 31a of the first and second wirings 30 and 31 over one another or placing them in close proximity to one another, to allow the first and second wiring 30 and 31 to be moved relative to the other at their intermediate portions 30a and 31a. Thus, each of the exemplary embodiments provide the common effects of securing optimal play in the length of the first and the second wirings 30 and 31 for transferring needle-bar case 5, while holding the wirings 30 and 31 with appropriate tension applied on one another. Hence, even if needle-bar case 5 is transferred, variance in the tension of the first and second wirings 30 and 31 can be restrained as much a possible while establishing a hold of their intermediate portions 30a and 31a without slack to reliably prevent damaging and disconnection etc., of the wirings.
In the above described exemplary embodiments, the first and second wirings 30 and 31 are not limited to lead wires but may employ other cords that are capable of transmitting signals. One or more than one wirings may be gathered for the first and second wirings 30 and 31 respectively.
The fasteners that fasten the first and second wirings 30 and 31 to sewing machine body 7 side or the needle-bar case 5 side are not limited to body side fastener 45 or needle-bar case side fasteners 33a and 33b but may employ a couple fasteners that fasten the first and second wirings 30 and 31 respectively at sewing machine body 7 side and a separate couple of fasteners that fasten the first and second wirings 30 and 31 at the needle-bar case 5 side, meaning that four fasteners constitute the fastening element.
The electrical components are not limited to lights 27a and 27b but may comprise any other electrical components.
The foregoing description and drawings are merely illustrative of the principles of the present disclosure and are not to be construed in a limited sense. Various changes and modifications will become apparent to those of ordinary skill in the art. All such changes and modifications are seen to fall within the scope of the disclosure as defined by the appended claims.
Number | Date | Country | Kind |
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2009-079168 | Mar 2009 | JP | national |