A support for enabling cutting of a linear product, such as an eavestrough debris guard, is disclosed. The eavestrough debris guard has a top, two sides, a bottom, and a non-linear profile. The support includes a contoured top complementary to a bottom portion of the non-linear profile. The support includes a plurality of surfaces extending from the contoured top positioned to engage with the two sides of the linear product. The support includes a plurality of contoured portions each coupled to one of the surfaces positioned to engage with the top of the linear product. The support includes a gap passing through the contoured top and the plurality of surfaces shaped and dimensioned to allow passage of at least a portion of a cutting tool.

A method for feeding a web of printing material in a manufacturing system for producing packages, includes feeding the web from a web-fed printing press to a flat-bed machine for die-cutting or embossing while the printing press is in operation. An inserting device is used for winding the web onto an auxiliary wind-up device, moving a web-guiding element having a roller in a compensatory manner to achieve a temporary standstill of the web by converting a continuous movement of the web into an iterative movement by changing a speed of the web through changes of position of the roller, clamping the web while being cut by using a clamping unit, cross-cutting the web creating a cross cut edge by using a cutting unit adjacent the clamping unit, and inserting the web, cross cut edge first, into the flat-bed machine for at least one of die-cutting or embossing.

A method for feeding a web of printing material in a manufacturing system for producing packages, includes feeding the web from a web-fed printing press to a flat-bed machine for die-cutting or embossing while the printing press is in operation. An inserting device is used for winding the web onto an auxiliary wind-up device, moving a web-guiding element having a roller in a compensatory manner to achieve a temporary standstill of the web by converting a continuous movement of the web into an iterative movement by changing a speed of the web through changes of position of the roller, clamping the web while being cut by using a clamping unit, cross-cutting the web creating a cross cut edge by using a cutting unit adjacent the clamping unit, and inserting the web, cross cut edge first, into the flat-bed machine for at least one of die-cutting or embossing.

In order to be able to slice product pieces, whose cross-section varies along their length, into weight-accurate slices, after pressing to a uniform product caliber it is possible to measure these realistically in terms of cross-sectional area and length and not in a pumped up state of the machine. On the one hand, this is promoted by the fact that even before pressing, a cross-press stamp is set to a forming tube cross-section oriented to the unpressed product piece. On the other hand, this is promoted by the fact that after pressing, by lowering pressing force to a substantially lower holding force, it is possible to deform back the deformed, pumped up machine parts before measuring the product caliber.

The present invention relates to an electrode cutting apparatus including a separated foreign matter removal unit capable of immediately removing separated foreign matter generated at the time of electrode cutting through a blow unit and a suction unit configured to be repeatedly operated and stopped according to an electrode cutting operation in order to remove separated foreign matter generated when the electrode cutting apparatus performs electrode cutting.

A package for a size-in-store window covering comprises a box having a first portion that extends for the width of the window covering and a second portion that extends for less than the width of the window covering. The window covering extends beyond an end of a bottom wall a first distance and the head rail extends beyond an end of a first side wall a second distance. A method of cutting a window covering comprises providing a window covering in a box as described above and positioning the box with the exposed portion of the window covering facing down and the exposed portion of the head rail facing a clamp. Methods of packaging a window covering comprise reducing the total number of loops in the window covering, and positioning inserts between adjacent components.

A package for a size-in-store window covering comprises a box having a first portion that extends for the width of the window covering and a second portion that extends for less than the width of the window covering. The window covering extends beyond an end of a bottom wall a first distance and the head rail extends beyond an end of a first side wall a second distance. A method of cutting a window covering comprises providing a window covering in a box as described above and positioning the box with the exposed portion of the window covering facing down and the exposed portion of the head rail facing a clamp. Methods of packaging a window covering comprise reducing the total number of loops in the window covering, and positioning inserts between adjacent components.

In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

A manufacturing method includes locking a material to be cut against a cutting bed, stabilizing the material against the cutting bed, and cutting the material.

An electromechanical double-bladed fruit and vegetable peeling and cutting machine comprising a holding mechanism (1), a peeling mechanism (2), and a cutting mechanism (3) sequentially provided in a direction of fruit and vegetable processing. The holding mechanism receives and holds a fruit or vegetable, and pushes the fruit or vegetable toward the peeling mechanism for positioning. The peeling mechanism performs positioning, measures actual cutting height of the fruit or vegetable, and adaptively peels the fruit or vegetable by means of two peeling blades. The cutting mechanism removes a top and a bottom portion of the peeled fruit or vegetable, and cuts the fruit or vegetable into pieces. A processing method for the electromechanical double-bladed fruit and vegetable peeling and cutting machine is also disclosed, and comprises: using a holding mechanism to hold and fix a fruit or vegetable in a processing position; using a peeling structure to accurately measure the height of the fruit or vegetable to be processed; using two peeling blades to efficiently and adaptively peel the fruit or vegetable; and finally engaging a pushing cylinder (27), to sequentially push multiple fruits and vegetables toward a cutting blade (37) such that the fruits and vegetables are cut into pieces. A third telescopic cylinder participates in the processing steps by pushing cutting blades such that the bottoms and the tops of the fruits and vegetables are removed. The invention reduces processing time, and improves productivity.