This application is based upon and claims the benefit of priority from the prior Japanese Patent Application 2010-128826, filed on Jun. 4, 2010, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a needle plate provided with a first needle plate fixed to a sewing machine bed and a second needle plate detachably attached to the first needle plate.
Needle plates provided in conventional sewing machines are screw fastened to the upper surface of the sewing machine bed. Such needle plates are typically provided with a needle hole allowing penetration of a sewing needle and angular holes through which a feed dog for feeding a workpiece cloth is driven up and down. Within the bed below the needle plate, a horizontal hook mechanism is provided. When the horizontal hook mechanism needs to be accessed, for instance, to remove thread caught up in the horizontal hook mechanism or to clean the horizontal hook mechanism and its surroundings for maintenance purposes, the needle plate is removed by loosening the screw to expose the horizontal hook mechanism and its surroundings. When reattaching the needle plate to the bed, the needle plate needs to be carefully located with the sewing needle and the feed dog. Mislocation of the needle plate may cause unwanted contact with the sewing needle and the feed dog, possibly leading to mechanical damages.
To address such concerns, a needle plate was conceived that comprises a first needle plate provided with a needle hole and angular holes, and a second needle plate situated above the horizontal hook mechanism. This type of needle plate is provided with an engagement mechanism for establishing engagement between the first needle plate and the second needle plate, and a disengagement button that cancels the engagement of the engagement mechanism through user operation performed from the top side of the needle plate. The engagement mechanism is provided with a protrusion that is formed at the first needle plate and a slot being defined on a leaf spring provided at the second needle plate, which are mated to establish the engagement. The engagement is cancelled by depressing the disengagement button. Thus, second needle plate alone can be removed from the bed with the first needle plate staying secured on the bed.
The above described configuration, however, requires a two-step operation to remove the second needle plate. More specifically, the two-step operation includes a first operation in which the disengagement button is depressed against the elasticity of the leaf spring and a second operation in which the second needle plate is pulled away from the first needle plate while the disengagement button is depressed. However, not only is the two-step operation cumbersome but is also hard to carry out because the first operation is performed in one direction and the second operation is performed in another.
One object of the present disclosure is to provide a needle plate that allows reliable attachment of the second needle plate to the first needle plate and that simplifies the attachment/detachment of the second needle plate to/from the first needle plate as much as possible. It is another object of the present disclosure to provide a sewing machine provided with such needle plate.
In one aspect, the present disclosure discloses a needle plate for placement on an upper surface of a sewing machine bed containing a horizontal hook mechanism, the needle plate including a first needle plate that is secured on the sewing machine bed and that includes a needle hole allowing penetration of a sewing needle and an angular hole allowing protruding and retracting of a feed dog that feeds a workpiece cloth; a second needle plate that is disposed adjacent to the first needle plate and above the horizontal hook mechanism, the second needle plate being detachably attached to the first needle plate; an engagement mechanism that includes an engagement member formed at the first needle plate and an engagement subject member formed at the second needle plate, wherein the second needle plate is retained with the first needle plate through engagement of the engagement member and the engagement subject member; and a switching element that allows switching in positioning of the second needle plate relative to the first needle plate between the first position and the second position, the second needle plate, when in the first position, being secured in intimate contact with the first needle plate with the engagement mechanism in an engaged state, and the second needle plate, when in the second position, being distanced from the first needle plate with the engagement mechanism in a disengaged state.
In another aspect, the present disclosure discloses A sewing machine includes a sewing machine bed that contains a horizontal hook mechanism; and a needle plate placed on an upper surface of the sewing machine bed, the needle plate including: a first needle plate that is secured on the sewing machine bed and that includes a needle hole allowing penetration of a sewing needle and an angular hole allowing protruding and retracting of a feed dog that feeds a workpiece cloth; a second needle plate that is disposed adjacent to the first needle plate and above the horizontal hook mechanism, the second needle plate being detachably attached to the first needle plate; an engagement mechanism that includes an engagement member formed at the first needle plate and an engagement subject member formed at the second needle plate, wherein the second needle plate is retained with the first needle plate through engagement of the engagement member and the engagement subject member; and a switching element that allows switching in positioning of the second needle plate relative to the first needle plate between the first position and the second position, the second needle plate, when in the first position, being secured in intimate contact with the first needle plate with the engagement mechanism in an engaged state, and the second needle plate, when in the second position, being distanced from the first needle plate with the engagement mechanism in a disengaged state.
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.
A first exemplary embodiment of the present disclosure will be described with reference to
As typically shown in
On the front face of arm 3, various switches 5 are provided whereas on the front face of pillar 2, a wide liquid crystal display 6 hereinafter also referred to as LCD 6 is provided.
Arm 3 contains a sewing machine main shaft not shown that extends in the left and right direction as well as a sewing machine motor not shown that rotates the sewing machine main shaft. Though not shown in detail, head 4 contains a needle bar that has sewing needle 7 attached to its lower end. Near sewing needle 7, presser foot 8a is provided for depressing workpiece cloth not shown. Though not shown, arm 3 further contains components such as a needle-bar drive mechanism, a needle-bar swing mechanism, and thread take-up mechanism. The needle-bar drive mechanism drives the needle bar up and down based on the rotation of the sewing machine main shaft. The needle bar swing mechanism swings the needle bar in the left and right direction orthogonal to the direction in which the workpiece cloth is fed. The thread take-up mechanism drives a thread take-up not shown up and down in synchronism with the up and down movement of the needle bar.
On the upper surface of bed 1, needle plate 10 is provided. Though not shown in detail, within bed 1 below needle plate 10, a feed mechanism is provided that moves feed dog 8b shown in
Next, needle plate 10 will be discussed with reference to
As shown in
First needle plate 11 is made of a metal material and is generally rectangular. First needle plate 11 is provided with needle hole 13 that allows penetration of sewing needle 7, and a plurality of angular holes 14 through which feed dog 8b protrudes or retracts to feed the workpiece cloth. The first exemplary embodiment exemplifies 7 angular holes 14. Needle hole 13 is formed as a laterally elongate curve, whereas each of angular holes 14 is formed as a thin straight line running in the front and rear direction so as to collectively encompass needle hole 13. First needle plate 11 is further provided with a couple of through holes 15 through which screws 15a shown in
At the end of forward contact section 17a of contact member 16, a narrow guide piece 17b is formed that extends longitudinally.
The free end at the extremity of guide piece 17d is formed into guide head 17e that, when engaged with a later described emboss 43, places second needle plate 12 in intimate contact with first needle plate 11. Guide piece 17d, being bendable, acts like a spring member to urge second needle plate 12 in a gapless intimate contact with first needle plate 11 by way of emboss 43. Rearward contact section 17c located at the reward portion of contact member 16 is clamped between the underside of second needle plate 12 located above it and a later described clamp section 47a of retaining member 47 located below it as can be seen in
Referring now to
Second needle plate 12, on the other hand, may be made of metal plate and is configured in L-shape in plan view that extends along the front and the left edges of first needle plate 11. As can be seen in
Referring now to
Second bobbin thread guide plate 25 is provided with retaining member attachment 25a at the right side of needle plate cover 23. Retaining member attachment 25a allows attachment of elastic retaining member 30 that presses needle plate cover 23 leftward. The elasticity of retaining member 30 unremovably locks needle plate 23 in place. When retaining member 30 is urged rightward away from needle plate cover 23 against the elasticity, removal of needle plate cover 23 is permitted. Removal of needle plate cover 23 from opening 22 through the operation of retaining member 30 permits access through opening 22 and bobbin slot 28 for installing bobbin into horizontal hook mechanism 9.
First bobbin thread guide plate 24 is provided with cover attachment 24a on the left side of needle plate cover 23. Cover attachment 24a allows attachment of cover 31 made of synthetic resin as shown in
Referring now to
Thus, engagement established between engagement tongues 19a to 19c and engagement catches 32a to 32c determines the longitudinal and lateral positioning of second needle plate 12 relative to first needle plate 11 as well as maintaining the structural integrity of needle plate 10 as a whole. Engagement tongues 19a to 19c, engagement catches 32a to 32c, rear contact section 17c, and clamp section 47a constitute engagement mechanism 33 of the first exemplary embodiment.
Needle plate 10 is further provided with switching element 35 that switches the engagement status of engagement mechanism 33 between the engaged state in which the second needle plate 12 is placed in intimate contact with first needle plate 11 and the disengaged state in which second needle plate 12 is separated away from first needle plate 11. The structure and the working of switching element 35 will be described with reference to
As can be typically seen in
Referring to
As can be seen in
As can be typically seen in
A triangular cam in this context has a perimeter obtained by linking the circumferences of 3 circles each being centered on a vertex of a given triangle. The circles centered on the two opposing vertexes differ in their measurement of radii. The triangular cam is configured to rotate about one of the three vertexes of the triangle. The perimeter of the triangular cam can be obtained by adding the radii of the circles. The cam follower being moved by the rotation of the triangular cam normally contacts the triangular cam at least from two sides. Thus, the triangular cam rotates smoothly to allow the designed movement of the cam follower.
According to the first exemplary embodiment, as typically shown in
From the underside of second needle plate 12, emboss 43 protrudes downward in the proximity of attachment hole 36. In the first exemplary embodiment, emboss 43 is configured to be structurally integral with the underside of second needle plate 12. Emboss 43 limits the range of rotational movement of activation cam 39 to the first position shown in
Retaining subject 40 is disc shaped and formed on the underside of activation cam 39. As shown in
Referring now to
Retaining member 47 has, at the rear end of attachment 47b, lock member 47f bending upward in L-shape. Lock member 47f is engaged with lock slot 46 to prohibit turning of retaining member 47. Operable member 37, when rotated, exerts force on retaining member 47 in the direction of rotation. Though retaining member 47 is fastened by screw 45a, it is repeatedly subjected to the rotational force. Thus, screw 45a may loosen over time to cause the rotation of retaining member 47 and consequently displacing it from its original position. Lock member 47f eliminates such disadvantage by preventing rotational displacement of retaining member 47 through its secure locking. Retaining member 47 is further provided with clamp section 47a which is bent downward like a crank and which is located on the right side portion of attachment section 47b. When second needle plate 12 is attached to first needle plate 11, rear contact section 17c of contact member 16 is clamped between the underside of second needle plate 12 located above it and clamp section 47a located below second needle plate 12 as shown in
Next, a description will be given on the working of the above described needle plate 10.
As shown in
By switching operable member 37 from the second position to the first position, the operator is allowed to attach second needle plate 12 to first needle plate 11 from the unattached state. To elaborate on the switching, the operator may insert the tip of a tool not shown such as a screw driver into recess 38a of operable member 37 and turn operable member 37 from the second position to the first position. This switching causes activation cam 39 to turn in the direction of arrow 51 indicated in
As operable member 37 is switched to the first position, groove 40a travels to the first position and is placed in fitting engagement, which may be perceived as a clicking, with ridge 47e of retaining member 47 to lock operable member 37 at the first position. Under such state, activation cam 39 and contact member 16 are placed in contact at point P1F and point P1R to unmovably lock second needle plate 12 in attachment with first needle plate 11. Further, engagement tongues 19a to 19c and engagement catches 32a to 32c establish a longitudinal fitting engagement as can be seen in
Second needle plate 12 shown in
At this instance, point P1F, point P1R, and rotation center are substantially collinear, and the imaginary line interconnecting the foregoing is oriented in the front and rear direction. Thus, even when forward external force is exerted on second needle plate 12 from the rear side of the second needle plate 12 being attached to first needle plate 11, no momentum is exerted in the direction to turn activation cam 39. Thus, even if second needle plate 12 is subjected to such external force, the second needle plate 12 will not be detached from first needle plate 1.
Detachment of second needle plate 12 from first needle plate 11 can be done by merely switching operable member 37 from the first position to the second position. That is, as described earlier, the tip of the tool is inserted into recess 38a of operable member 37 to turn operable member 37 from the first position to the second position. The switching operation causes activation cam 39 to be turned in the direction of arrow 52 indicated in
As operable member 37 is switched to the second position, groove 40a travels to and is placed in fitting engagement, which may be perceived as a clicking, with ridge 47e of retaining member 47 to lock operable member 37 at the second position. Under such state, activation cam 39 and contact member 16 are placed in contact at point P2F and point P2R to move second needle plate 12 away from first needle plate 11 by distance L. Further, the engagement between engagement tongues 19a to 19c and engagement catches 32a to 32c and between rear contact portion 17c and clamp section 47a are cancelled. Thus, the operator may readily remove second needle plate 12 from first needle plate 11.
Distance L taken in the front and rear direction by second needle plate 12 away from first needle plate 11 relies on the configuration of cam mechanism 44. More specifically, distance L is determined by the difference in the distance between contact point P1F and rotation center 42 and the distance between contact point P2F and rotation center 42. Thus, distance L can be controlled to a given distance through modification of design such as the shape of activation cam 39.
As described above, needle plate 10 according to the first exemplary embodiment is provided with switching element 35 that switches second needle plate 12 between the first position in which second needle plate 12 is locked in intimate contact with first needle plate 11 with engagement mechanism 33 in the engaged state, and the second position in which second needle plate 12 is moved away from first needle plate 11 with engagement mechanism 33 in the disengaged state.
According to the above described configuration, second needle plate 12 can be removed from first needle plate 11 through switch operation of switching element 35 from the first position to the second position to thereby place engagement mechanism 33 in the disengaged state and moving second needle plate 12 away from first needle plate 11. This means that a single operation of switching element 35 allows disengagement and thus, the detachment of second needle plate 12 from first needle plate 11. The above described configuration simplifies the detachment of second needle plate 12 from first needle plate 11. In contrast, when switch element is in the first position, second needle plate 12 is placed in intimate contact with first needle plate 11. Further, when switching element 35 is in the first position, second needle plate 12 is reliably retained in attachment to first needle plate 11 through engagement between engagement portions 19a to 19c and engagement subject portions 32a to 32c and between rear contact portion 17c and clamp section 47a. Thus, second needle plate 12 can be reliably attached to first needle plate 11.
Switch operation of switching element 35 from the second position to the first position causes conjunctive movement of second needle plate toward the direction to be in intimate contact with first needle plate such that engagement mechanism 33 is placed in the engaged state. Likewise, switch operation of switching element 35 from the first position to the second position causes conjunctive movement of second needle plate toward the direction to move away from the first needle plate such that engagement mechanism 33 is placed in the disengaged state.
According to the above described configuration, attachment and detachment of second needle plate 12 to from first needle plate 12 can be done through the switching operation of switching element 35 from the first position to the second position. Further, the movement of second needle plate 12 can be made conjunctive with the switching operation of switching element 35 to facilitate the attachment/detachment of second needle plate 12 to/from first needle plate 11 which improves the usability of the sewing machine.
Switching element 35 includes disc 38 of operable member 37 provided at one of first needle plate 11 and second needle plate 12, activation cam 39 moving conjunctively with disc 38, and contact member 16 provided on the remaining other of the needle plates 11 and 12 and being placed in contact with activation cam 39. Disc 38 provided at operable member 37 moves in conjunction with activation cam 39 which is placed in contact with contact member 16. The change in contact position of activation cam 39 in coordination with the switching of operable member 37 between the first position and the second position causes the approximation/separation of second needle plate 12 to/from first needle plate 11.
According to such configuration, switching element 35 places second needle plate 12 in intimate contact with or spaced away from first needle plate 11 through change in the contact position of activation cam 39 relative to contact member 16 which is caused by the switch operation of operable member 37 by the user. The above is rendered in a simple structure of disc 38, activation cam 39, and contact member 16. Further, second needle plate 12 can be removed from first needle plate 11 only when engagement mechanism 33 is disengaged by the user operation of operable member 37.
Switching element 35 according to the first exemplary embodiment is configured to detachably attach second needle plate 12 to first needle plate 11 through the operation of cam mechanism 44, thereby smoothly and reliably attaching/detaching second needle plate 12 to/from first needle plate 11 by way of activation cam 39. Operable member 37 and retaining member 47 provided on first needle plate 11 and contact member 16 provided on second needle plate 12 are interchangeable, meaning that the former may be provided on second needle plate 12 and the later may be provided on first needle plate 11.
Switching element 35 is provided between either of needle plates 11, 12 and operable member 37, and is provided with retaining member 47 that retains operable member 37 either in the first position or the second position.
According to such configuration, second needle plate 12 can be locked in intimate contact with first needle plate 11 by placing operable member 37 in the first position to reliably attach second needle plate 12 to first needle plate 11. By placing operable member 37 in the second position, second needle plate 12 can be reliably disengaged from first needle plate 11 to allow second needle plate 12 to be separated from first needle plate 11. Thus, attachment/detachment of second needle plate 12 to/from first needle plate 11 can be made easier.
Upper surface 37a of operable member 37 is configured to be level with the upper surface of second needle plate 12 to obtain a flat and smooth surface which prevents the workpiece cloth from being caught on needle plate 10 when placed on needle plate 10 typically during a sewing operation, thereby improving the work efficiency by eliminating such interruptions.
Operable member 37, being pivoted on either of needle plates 11 and 12, allows attachment/detachment of second needle plate 12 to/from first needle plate by rotary operation, which simplifies the structure of switching element 35 as well as improving operability.
Recess 38a provided on upper surface 37a of operable member 37 allows turning of operable member 37 through use of a tool, thereby further facilitating attachment/detachment of second needle plate 12 to/from first needle plate 11.
Switching element 60 according to the second exemplary embodiment differs from switching element 35 of the first exemplary embodiment as described below. On the underside of second needle plate 12, a couple of embosses 61 and 62 are provided in addition to emboss 43. Both embosses 61 and 62 are identical in shape to emboss 43 and are structurally integral with second needle plate 12. Emboss 61 is provided on the rear end side of second needle plate 12, whereas emboss 62 is located forward relative to emboss 43. Emboss 61 is provided on one lateral side of second needle plate 12 relatively closer to first needle plate 11, whereas emboss 62 is provided on the opposing other lateral side of second needle plate 12 relatively distant from first needle plate 11.
Embosses 61 and 62 are inserted through guide sections 63 and 64 provided on contact member 16′. Guide section 63 is located at the rear end side of contact member 16, whereas guide section 64 is located forward relative to forward contact section 17a. Guide section 63 is generally shaped as a long hole to allow insertion of emboss 61. The length of guide section 63 running longitudinally is dimensioned slightly longer than distance L to allow longitudinal movement of second needle plate 12. Guide section 63 is provided with a pair of slopes 63a and 63a spreading forward that increases the width of guide section 63 in the forward direction. Guide section 64, on the other hand, is formed as an opening that is opened forward to exhibit a forwardly protruding bifurcation at forward contact section 17a. Guide section 64 is provided with a pair of forwardly spreading slopes 64a and 64a that are located at the forward tip of the bifurcation and that increase the width of guide section 64 in the forward direction. Contact member 16′ according to the second exemplary embodiment is provided with guide tip 17d′ which is relatively thicker as compared to guide tip 17d of the first exemplary embodiment.
According to the above described switching element 60, switching of operable member 37 from the second position to the first position causes second needle 12 to be guided by inner walls 63b and 64b of guide sections 63 and 64 by way of embosses 61 and 62. Thus, when operable member 37 is placed at the first position as shown in
Second needle plate 70 according to the third exemplary embodiment is made entirely of synthetic resin material and lacks components such as the pair of guide plates 24 and 25 and screws 26 and 27 provided in second needle plate 12 of the first exemplary embodiment. As can be seen in
Referring to
Switching element 75 according to the third exemplary embodiment is configured such that operable member 77 and activation cam 78 are configured as separate components and retaining member 79 is structurally integral with second needle plate 70 as shown in
As shown in
Attachment of switching element 75 to second needle plate 70 begins with laterally inserting activation cam 78 between second needle plate 70 and annular section 79a. Then, protrusion 77a and auxiliary protrusion 77b of operable member 77 are pressed into fitting engagement with recess 78a and auxiliary recess 78b from the top side of second needle plate 70. Thus, operable member 77 and activation cam 78 are rotatably supported by support section 36a of attachment hole 36 as can be seen in
According to the above described configuration, retaining member 79, clamp section 47a′, and second needle plate 70 are made of synthetic resin material and are structurally integral which advantageously reduces number of components and cost. Further, second needle plate 70 can be reliably attached to first needle plate 11 by the working of engagement mechanism 73 and switching element 75 to provide but not limited to advantages offered by the first exemplary embodiment.
The present disclosure is not limited to the exemplary embodiments heretofore described or shown but may be modified or expanded as follows.
The needle plate described above is not limited for application in household sewing machine M but may be applied to industrial sewing machines in general. The upper surface of the operable member may be configured to be slightly lower than the upper surfaces of the first needle plate or the second needle plate. The engagement mechanism only requires that an engagement section is provided on the first needle plate and an engagement subject is provided on the second needle plate. The disengaged state of the engagement mechanism only requires that the engagement between the engagement section and the engagement subject are cancelled to allow detachment of the second needle plate from the first needle plate. Switching element 75 in its entirety including the contacting member 16 may be made of synthetic resin.
While various features have been described in conjunction with the examples outlined above, various alternatives, modifications, variations, and/or improvements of those features and/or examples may be possible. Accordingly, the examples, as set forth above, are intended to be illustrative. Various changes may be made without departing from the broad spirit and scope of the underlying principles.
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Office Action issued in Japanese Patent Application No. 2009-003468 dated May 10, 2011 (with translation). |
U.S. Appl. No. 13/310,198, filed Dec. 2, 2011 in the name of Kenichi Mizuno et al. |
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Number | Date | Country | |
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20110297063 A1 | Dec 2011 | US |