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Barudan Punchant Apr 2026

Schiffli machines are the massive, 15-yard-long behemoths that produce lace, eyelet, and bridal fabric. They use a continuous thread and a pantograph to move hundreds of needles at once. Schiffli lace has a distinct "hand" (feel)—it is soft, drapey, and has a tactile roughness on the back.

The Punchant worked via direct vector interpolation . You physically traced the edge of your design with a puck, and the machine interpreted the pressure, speed, and angle of your hand. This introduced micro-variance . In chemical lace, where you dissolve the backing and only the thread remains, those micro-variances are what prevent the fabric from curling into a plastic cup. The Punchant created "breathing room" in the stitch density that algorithms cannot replicate. To understand the Punchant, you have to understand Schiffli embroidery . Barudan Punchant

The Punchant’s secret sauce wasn't the hardware; it was the . The Punchant worked via direct vector interpolation

Because the Punchant's processor was so slow (we're talking 8MHz), it couldn't store complex shape data. Instead, it stored commands . "Go left. Satin stitch, width 1.2mm. Density 4. Stop." The actual curve was drawn by the machine's real-time kinematics. In chemical lace, where you dissolve the backing

To the uninitiated, the Barudan Punchant (often stylized as Punchant or Punch-lant ) looks like a relic. It’s a standalone, dedicated digitizing workstation that peaked in the late 1980s and early 1990s. It has a monochrome CRT screen, a proprietary puck (tablet), and a user interface that makes DOS look like iOS.

And yet, in 2026, a well-maintained Punchant system still trades hands for thousands of dollars. Why?

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Schiffli machines are the massive, 15-yard-long behemoths that produce lace, eyelet, and bridal fabric. They use a continuous thread and a pantograph to move hundreds of needles at once. Schiffli lace has a distinct "hand" (feel)—it is soft, drapey, and has a tactile roughness on the back.

The Punchant worked via direct vector interpolation . You physically traced the edge of your design with a puck, and the machine interpreted the pressure, speed, and angle of your hand. This introduced micro-variance . In chemical lace, where you dissolve the backing and only the thread remains, those micro-variances are what prevent the fabric from curling into a plastic cup. The Punchant created "breathing room" in the stitch density that algorithms cannot replicate. To understand the Punchant, you have to understand Schiffli embroidery .

The Punchant’s secret sauce wasn't the hardware; it was the .

Because the Punchant's processor was so slow (we're talking 8MHz), it couldn't store complex shape data. Instead, it stored commands . "Go left. Satin stitch, width 1.2mm. Density 4. Stop." The actual curve was drawn by the machine's real-time kinematics.

To the uninitiated, the Barudan Punchant (often stylized as Punchant or Punch-lant ) looks like a relic. It’s a standalone, dedicated digitizing workstation that peaked in the late 1980s and early 1990s. It has a monochrome CRT screen, a proprietary puck (tablet), and a user interface that makes DOS look like iOS.

And yet, in 2026, a well-maintained Punchant system still trades hands for thousands of dollars. Why?