N/A.
This invention relates generally to sewing machines, and more particularly to industrial sewing machines having the capability of sewing relatively thinner materials and relatively thicker materials.
Industrial sewing machines have long been used for sewing together relatively thinner materials and relatively thicker materials. One example of a relatively thicker material is a mattress panel. Sewing machines used for sewing such thicker materials must be adapted to provide adequate vertical clearance for the material to fit through the throat of the machine. The throat plate or needle plate, the plate upon which the material rests as it is sewed, defines the bottom plane of the space in which the material must fit in the throat of the machine. The thickness of the material which can be sewn by the machine is dictated by the clearance between the throat plate and the needle, presser foot, and upper walking foot or top feed dog when at their upper travel limits.
One type of industrial sewing machine, which is particularly adapted for sewing thicker materials, utilizes an upper walking foot and a lower feed dog (sometimes referred to as “top and bottom feed”), and is configured to impart out-of-phase reciprocatory movement of the presser foot and walking foot. Such a sewing machine is shown in U.S. Pat. Nos. 4,449,464 and 5,309,854. In this type of sewing machine, the upper walking foot travels in a more or less elliptical motion during sewing, and thus has a horizontal motion component (stepping length or feed length) and a vertical motion component (stepping height). While current such sewing machines may have a means for readily adjusting the feed length of the upper walking foot, adjustment of the stepping height of the upper walking foot is typically much more cumbersome and time consuming. Examples of such machines are the Pegasus EXT3200 Series and EXT5200 Series of industrial sewing machines. These machines have a combination knob and lever to adjust the feed length. However, to adjust the stepping height, a qualified technician must turn the machine pulley, loosen certain screws, manipulate the top feed dog and link, set the height of the top feed dog for the desired material thickness, and once at the correct height, retighten the screws.
It is thus desirable to provide a sewing machine of the type that utilizes an upper walking foot and a lower feed dog and that imparts out-of-phase reciprocatory movement of the presser foot and walking foot, with a means for readily adjusting the stepping height in order to more quickly and easily configure the machine for sewing thicker materials.
In one aspect, a sewing machine comprises a crank shaft, a first drive shaft, a second drive shaft, a needle assembly, a presser foot, and an upper walking foot. A first crank arm assembly is connected to the crank shaft to the first drive shaft. A first linkage assembly is connected to the first drive shaft to the needle assembly. A second crank arm assembly is connected to the first drive shaft to the second drive shaft. A second linkage assembly is connected to the second drive shaft to the presser foot and the upper walking foot. The second linkage assembly is configured to cause out-of-phase reciprocatory movement of the presser foot and the upper walking foot. The second crank arm assembly has a variable length that is selectably adjustable by an operator to yield at least first and second different stepping heights of the upper walking foot.
The variable length second crank arm can also yield at least first and second different uppermost travel limits of the presser foot.
The first crank arm assembly can include a first crank arm and a first crank lever. The first crank arm can be pivoted at a first end to the crank shaft. The first crank lever can be fixedly secured at a first end to the first drive shaft. The first crank arm and the first crank lever can be pivotally connected at respective second ends.
The second crank arm assembly can include a second crank arm and a second crank lever. The second crank arm can be pivoted at a first end to the first crank lever. The second crank lever can be fixedly secured at a first end to the second drive shaft. The second crank arm and the second crank lever can be translationally and pivotally connected at respective second ends.
One of the second crank arm and the second crank lever can include a pin and the other of the second crank arm and the second crank lever can include an elongated slot. The pin can ride in the slot. The position of the pin along a length of the slot can be selectably adjustable by an operator. Preferably the second crank arm includes the pin and the second crank lever includes the slot.
The sewing machine can further include a lead screw selectably rotatable by an operator and configured to translate the pin along the length of the slot providing a low stepping height of the walking foot, a high stepping height of the walking foot, and a plurality of stepping heights between the low stepping height and the high stepping height. In other words, the lead screw provides the capability having essentially continuous or infinite adjustability of the stepping height between the low stepping height and the high stepping height.
The lead screw can include a knob that is manually rotatable by an operator to rotate the lead screw. The lead screw can include a block that translates generally horizontally in response to rotation of the lead screw. An end of the pin can ride in the block. The second linkage assembly, the first crank arm assembly, and the second crank arm assembly can be configured to cause the end of the pin to translate generally vertically in the block in response to the block translating generally horizontally. In doing so, the distance between a center line of the second drive shaft and a center line of the pin to can be selectably varied. The block can include a generally vertically extending channel. The end of the pin can have a cross-section that mates with a cross-section of the channel.
Alternatively, the sewing machine can include a pneumatic cylinder actuatable by an operator and configured to translate the pin along the length of the slot providing a low stepping height of the walking foot and a high stepping height of the walking foot. Similar to the lead screw embodiment, the pneumatic cylinder can include the aforementioned block that translates generally horizontally in response to translation of a piston rod of the pneumatic cylinder.
In another aspect, a sewing machine comprises a crank shaft, a drive shaft, a needle assembly, a presser foot, and an upper walking foot. A crank arm connects the crank shaft and to the drive shaft. A linkage assembly connects the drive shaft to the needle assembly, the presser foot, and the upper walking foot. The linkage assembly is configured to cause out-of-phase reciprocatory movement of the presser foot and the upper walking foot. An adjustment mechanism is selectably adjustable by an operator that varies a center line to center line distance between two pivot axes of the linkage assembly to yield at least first and second different stepping heights of the upper walking foot.
The first and second links of the linkage mechanism can be translationally and pivotally connected at respective ends to provide the variable center line to center line distance between the two pivot axes of the linkage assembly. One of the first and second links can include a pin and the other of the first and second links can include an elongated slot. The pin can ride in the slot. A position of the pin along a length of the slot selectably can be adjustable by an operator.
The sewing machine can include a lead screw selectably rotatable by an operator and configured to translate the pin along the length of the slot providing a low stepping height of the walking foot, a high stepping height of the walking foot, and a plurality of stepping heights between the low stepping height and the high stepping height.
The lead screw can include a knob that is manually rotatable by an operator to rotate the lead screw. The lead screw can include a block that translates generally horizontally in response to rotation of the lead screw. An end of the pin can ride in the block. The linkage assembly can be configured to cause the end of the pin to translate generally vertically in the block in response to the block translating generally horizontally. In doing so, the center line to center line distance between the two pivot axes of the linkage assembly can be selectably varied. The block can include a generally vertically extending channel. The end of the pin can have a cross-section that mates with a cross-section of the channel.
Alternatively, the sewing machine can include a pneumatic cylinder actuatable by an operator and configured to translate the pin along the length of the slot providing a low stepping height of the walking foot and a high stepping height of the walking foot. Similar to the lead screw embodiment, the pneumatic cylinder can include the aforementioned block that translates generally horizontally in response to translation of a piston rod of the pneumatic cylinder.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the summary of the invention given above, and the detailed description of the drawings given below, serve to explain the principles of the present invention.
Referring to first to
Referring now to
A crank arm 60 is pivotally connected at its lower end to crank shaft 14 and is pivotally connected at its upper end to a front end of a crank lever 62 at 64. Crank lever 62 is fixedly connected at its opposite rear end to a drive shaft 66 as by a lock screw 68. A link or lever 70 is pivotally connected at its front end to an upper end of the needle assembly 16 at 72 and is fixedly connected at its opposite rear end to the drive shaft 66 as by a lock screw (not shown).
A second crank arm 80 is pivotally connected at its lower end to crank lever 62 at 82. The upper end of the crank arm 80 carries a pin 84. A second crank lever 86 has its rear end fixedly connected to a second drive shaft 88 as by a lock screw 90. The opposite front end of the second crank lever 86 has an elongated slot 92 therein. Pin 84 rides in slot 92.
The upper end of link 44 is pivotally connected to the rear end of a link or lever 94 at 96. The opposite front end of the link or lever 94 is fixedly connected to the second drive shaft as by a lock screw 100.
The linkage assembly 22 is configured to cause out-of-phase reciprocatory movement of the presser foot 18 and walking foot 20. Additional details of such a linkage assembly may be seen with reference to U.S. Pat. Nos. 4,449,464 and 5,309,854, hereby incorporated by reference herein as if fully set forth in their entirety.
With continued reference to
Block 128 includes a vertically oriented channel 142. Pin 84 has an end 144 that has a cross-section that mates with the cross-section of channel 144. Moving block 128 fore and aft translates channel 142 fore and aft which causes end 144 of pin 84 to translate fore and aft. To be able to travel fore and aft, end 144 of pin 84 must travel up and down in channel 142. (End 144 of pin 84 also travels up and down during articulation of linkage 22 caused by rotation of crank shaft 14.) Adjustment of lead screw 122 via knob 130 thus moves the center lines or pivot axes of pin 84 and second drive shaft 88 towards one another or away from one another. It is this selective adjustment of lead screw 122 via knob 130 that provides the first and second different stepping heights of the upper walking foot 20.
With reference to
With reference to
It will be appreciated that, due to the nature of the lead screw 122 and block 128, the stepping height of the walking foot 20 is continuously or infinitely variable between the low stepping height (
While a lead screw has been shown and described as the actuator for moving the block 128 fore and aft, note that most any type of actuator could be used. For example, referring now to
Note further that other actuators could also be used, such as a hydraulic cylinder, an electric motor (linear or rotary), an electric solenoid, etc. All such actuators are deemed to be embraced by the term “actuator” used as part of an “adjustment mechanism”, whether manually operated or powered by an external power source.
As used herein, the term “linkage” or “linkage assembly” shall be deemed to embrace an assemblage of multiple links having fixed and/or pivotal connections, as well as a single link or lever having fixed and/or pivotal connections at its opposite ends.
The various embodiments of the invention shown and described are merely for illustrative purposes only, as the drawings and the description are not intended to restrict or limit in any way the scope of the claims. Those skilled in the art will appreciate various changes, modifications, and improvements which can be made to the invention without departing from the spirit or scope thereof. The invention in its broader aspects is therefore not limited to the specific details and representative apparatus and methods shown and described. The invention resides in each individual feature described herein, alone, and in all combinations of any and all of those features. Departures may therefore be made from such details without departing from the spirit or scope of the general inventive concept. Accordingly, the scope of the invention shall be limited only by the following claims and their equivalents.