Calculadora de dise\u00f1o de resortes de compresi\u00f3n | Herramienta profesional de dise\u00f1o de resortes<\/title>\n <style>\n \/* Reset and base styles *\/\n * {\n margin: 0;\n padding: 0;\n box-sizing: border-box;\n }\n\n body {\n font-family: -apple-system, BlinkMacSystemFont, \"Segoe UI\", Roboto, Oxygen-Sans, Ubuntu, Cantarell, \"Helvetica Neue\", sans-serif;\n line-height: 1.6;\n color: #333;\n }\n\n \/* Calculator container *\/\n .calculator-container {\n background: #fff;\n border-radius: 8px;\n box-shadow: 0 2px 4px rgba(0,0,0,0.1);\n margin-bottom: 30px;\n }\n\n \/* Section styles *\/\n .section {\n margin-bottom: 30px;\n }\n\n h2 {\n color: #000;\n margin-bottom: 15px;\n font-size: 1.5em;\n }\n\n \/* Parameter explanations *\/\n .parameter-list {\n display: grid;\n grid-template-columns: repeat(auto-fit, minmax(250px, 1fr));\n gap: 15px;\n margin-bottom: 20px;\n }\n\n .parameter-item {\n background: #f8f9fa;\n padding: 10px;\n border-radius: 4px;\n }\n\n \/* Input form *\/\n .input-form {\n display: grid;\n gap: 15px;\n margin-bottom: 20px;\n \/* Default to one column *\/\n grid-template-columns: 1fr;\n }\n\n \/* Two columns on screens wider than 768px *\/\n @media (min-width: 769px) {\n .input-form {\n grid-template-columns: repeat(2, 1fr);\n }\n }\n\n .input-group {\n display: flex;\n flex-direction: column;\n }\n\n .input-group label {\n margin-bottom: 5px;\n font-weight: 500;\n }\n\n .input-group input,\n .input-group select {\n padding: 8px;\n border: 1px solid #ddd;\n border-radius: 4px;\n font-size: 16px;\n }\n\n \/* Calculate button *\/\n .calculate-btn {\n background: #007bff;\n color: white;\n border: none;\n padding: 12px 24px;\n border-radius: 4px;\n cursor: pointer;\n font-size: 16px;\n transition: background 0.3s;\n width: 25%;\n max-width: 200px;\n margin: 20px auto;\n display: block;\n \/* Make the button span all columns in the grid *\/\n grid-column: 1 \/ -1;\n }\n\n .calculate-btn:hover {\n background: #0056b3;\n }\n\n \/* Results section *\/\n .results {\n display: none;\n background: #e9ecef;\n padding: 20px;\n border-radius: 4px;\n margin-top: 20px;\n }\n\n .results.active {\n display: block;\n }\n\n .result-item {\n margin-bottom: 10px;\n font-size: 1.1em;\n }\n\n .result-value {\n font-weight: bold;\n color: #007bff;\n }\n\n \/* Responsive adjustments *\/\n @media (max-width: 768px) {\n .input-form {\n \/* One column on small screens - handled by default *\/\n }\n\n .parameter-list {\n grid-template-columns: 1fr;\n }\n }\n <\/style>\n<\/head>\n<body>\n <div class=\"calculator-container\">\n \n <div class=\"section section-parameters\">\n <h2>Par\u00e1metros<\/h2>\n <div class=\"parameter-list\">\n <div class=\"parameter-item\">\n <strong>Di\u00e1metro del alambre (d):<\/strong> El di\u00e1metro del alambre de resorte.\n <\/div>\n <div class=\"parameter-item\">\n <strong>Di\u00e1metro medio de la bobina (D):<\/strong> El di\u00e1metro medio de las espiras del resorte.\n <\/div>\n <div class=\"parameter-item\">\n <strong>N\u00famero de bobinas activas (Na):<\/strong> El n\u00famero de bobinas que contribuyen a la acci\u00f3n del resorte.\n <\/div>\n <div class=\"parameter-item\">\n <strong>Bobinas del asiento izquierdo (Nzl):<\/strong> N\u00famero de bobinas inactivas en el extremo izquierdo.\n <\/div>\n <div class=\"parameter-item\">\n <strong>Bobinas del asiento derecho (Nzr):<\/strong> N\u00famero de bobinas inactivas en el extremo derecho.\n <\/div>\n <div class=\"parameter-item\">\n <strong>Longitud libre (L0):<\/strong> La longitud del resorte cuando no est\u00e1 bajo carga.\n <\/div>\n <div class=\"parameter-item\">\n <strong>M\u00f3dulo de corte (G):<\/strong> Propiedad del material que indica rigidez al corte.\n <\/div>\n <div class=\"parameter-item\">\n <strong>Fuerza aplicada (N):<\/strong> La fuerza externa aplicada al resorte. (Ingrese N o L1, no ambos)\n <\/div>\n <div class=\"parameter-item\">\n <strong>Longitud bajo carga (L1):<\/strong> La longitud del resorte cuando se le aplica una fuerza. (Ingrese N o L1, no ambos)\n <\/div>\n <\/div>\n <\/div>\n\n \n <div class=\"section section-calculator\">\n <h2>Calculadora<\/h2>\n <form id=\"springCalculator\" class=\"input-form\" action=\"\">\n <div class=\"input-group\">\n <label for=\"wireDiameter\">Di\u00e1metro del alambre (d) <span class=\"unit\">mm<\/span><\/label>\n <input type=\"number\" id=\"wireDiameter\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"meanDiameter\">Di\u00e1metro medio de la bobina (D) <span class=\"unit\">mm<\/span><\/label>\n <input type=\"number\" id=\"meanDiameter\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"numberOfActiveCoils\">N\u00famero de bobinas activas (Na)<\/label>\n <input type=\"number\" id=\"numberOfActiveCoils\" step=\"0.1\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"freeLength\">Longitud libre (L0) <span class=\"unit\">mm<\/span><\/label>\n <input type=\"number\" id=\"freeLength\" step=\"0.1\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"shearModulus\">M\u00f3dulo de corte (G) <span class=\"unit\">N\/mm\u00b2<\/span><\/label>\n <input type=\"number\" id=\"shearModulus\" step=\"100\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"appliedForce\">Fuerza aplicada (N) <span class=\"unit\">norte<\/span><\/label>\n <input type=\"number\" id=\"appliedForce\" step=\"0.1\">\n <\/div>\n <div class=\"input-group\">\n <label for=\"lengthUnderLoad\">Longitud bajo carga (L1) <span class=\"unit\">mm<\/span><\/label>\n <input type=\"number\" id=\"lengthUnderLoad\" step=\"0.1\">\n <\/div>\n <div class=\"input-group\">\n <label for=\"leftSeatCoils\">Bobinas del asiento izquierdo (Nzl)<\/label>\n <input type=\"number\" id=\"leftSeatCoils\" step=\"0.1\" value=\"0\">\n <\/div>\n <div class=\"input-group\">\n <label for=\"rightSeatCoils\">Bobinas del asiento derecho (Nzr)<\/label>\n <input type=\"number\" id=\"rightSeatCoils\" step=\"0.1\" value=\"0\">\n <\/div>\n <button type=\"submit\" class=\"calculate-btn\">Calcule<\/button>\n <input type=\"hidden\" name=\"trp-form-language\" value=\"es\"\/><\/form>\n <\/div>\n\n \n <div id=\"results\" class=\"results section-results\">\n <h2>Resultados de los c\u00e1lculos<\/h2>\n <div class=\"result-item\">\n Tasa de resorte (k): <span class=\"result-value\" id=\"springRate\">0<\/span> N\/mm\n <\/div>\n <div class=\"result-item\">\n Altura s\u00f3lida: <span class=\"result-value\" id=\"solidHeight\">0<\/span> mm\n <\/div>\n <div class=\"result-item\" id=\"maxLoadResult\">\n Carga m\u00e1xima: <span class=\"result-value\" id=\"maxLoad\">0<\/span> norte\n <\/div>\n <div class=\"result-item\" id=\"maxDeflectionResult\">\n Deflexi\u00f3n m\u00e1xima: <span class=\"result-value\" id=\"maxDeflection\">0<\/span> mm\n <\/div>\n <div class=\"result-item\" id=\"forceAtL1Result\" style=\"display: none;\">\n Fuerza en la longitud L1: <span class=\"result-value\" id=\"forceAtL1\">0<\/span> norte\n <\/div>\n <div class=\"result-item\" id=\"deflectionAtNResult\" style=\"display: none;\">\n Desviaci\u00f3n ante la fuerza N: <span class=\"result-value\" id=\"deflectionAtN\">0<\/span> mm\n <\/div>\n <div class=\"result-item\">\n Di\u00e1metro interior (Di): <span class=\"result-value\" id=\"innerDiameter\">0<\/span> mm\n <\/div>\n <div class=\"result-item\">\n \u00cdndice de primavera (C): <span class=\"result-value\" id=\"springIndex\">0<\/span>\n <\/div>\n <div class=\"result-item\">\n Bobinas totales (Nt): <span class=\"result-value\" id=\"totalCoils\">0<\/span>\n <\/div>\n <div class=\"result-item\">\n Factor Wahl: <span class=\"result-value\" id=\"wahlFactor\">0<\/span>\n <\/div>\n <div class=\"result-item\" id=\"deflectionResult\" style=\"display: none;\">\n Desviaci\u00f3n (L): <span class=\"result-value\" id=\"deflection\">0<\/span> mm\n <\/div>\n <\/div>\n <\/div>\n\n <script>\n document.getElementById('springCalculator').addEventListener('submit', function(e) {\n e.preventDefault();\n\n \/\/ Get input values\n const d = parseFloat(document.getElementById('wireDiameter').value);\n const D = parseFloat(document.getElementById('meanDiameter').value);\n const Na = parseFloat(document.getElementById('numberOfActiveCoils').value);\n const L0 = parseFloat(document.getElementById('freeLength').value);\n const G = parseFloat(document.getElementById('shearModulus').value);\n const N = document.getElementById('appliedForce').value !== '' ? parseFloat(document.getElementById('appliedForce').value) : null;\n const L1 = document.getElementById('lengthUnderLoad').value !== '' ? parseFloat(document.getElementById('lengthUnderLoad').value) : null;\n const Nzl = parseFloat(document.getElementById('leftSeatCoils').value) || 0;\n const Nzr = parseFloat(document.getElementById('rightSeatCoils').value) || 0;\n\n\n \/\/ Calculate spring rate (k)\n \/\/ Formula: k = (G * d^4) \/ (8 * D^3 * Na)\n const k = (G * Math.pow(d, 4)) \/ (8 * Math.pow(D, 3) * Na);\n\n \/\/ Calculate solid height\n \/\/ Assuming squared ends, total coils = Na + 2. For other ends, this might differ. Using Na for a simplified solid height based on active coils * diameter\n const totalCoils = Na + Nzl + Nzr;\n const solidHeight = totalCoils * d;\n\n\n \/\/ Calculate maximum deflection (Deflection to Solid Height)\n const maxDeflection = L0 - solidHeight;\n\n \/\/ Calculate maximum load (Load at Solid Height)\n const maxLoad = k * maxDeflection;\n\n \/\/ Calculate Inner Diameter (Di)\n const innerDiameter = D - d;\n\n\n \/\/ Display results that are always calculated\n document.getElementById('springRate').textContent = k.toFixed(2);\n document.getElementById('solidHeight').textContent = solidHeight.toFixed(2);\n document.getElementById('maxLoad').textContent = maxLoad.toFixed(2);\n document.getElementById('maxDeflection').textContent = maxDeflection.toFixed(2);\n document.getElementById('innerDiameter').textContent = innerDiameter.toFixed(2);\n\n\n \/\/ Calculate results based on N or L1 input\n document.getElementById('forceAtL1Result').style.display = 'none';\n document.getElementById('deflectionAtNResult').style.display = 'none';\n document.getElementById('deflectionResult').style.display = 'none';\n\n let calculatedDeflection = 0;\n\n if (N !== null) {\n \/\/ Calculate deflection at Applied Force N\n calculatedDeflection = N \/ k;\n document.getElementById('deflectionAtN').textContent = calculatedDeflection.toFixed(2);\n document.getElementById('deflectionAtNResult').style.display = 'block';\n\n } else if (L1 !== null) {\n \/\/ Calculate deflection (delta L) = L0 - L1\n calculatedDeflection = L0 - L1;\n \/\/ Calculate force at Length L1\n const forceAtL1 = k * calculatedDeflection;\n document.getElementById('forceAtL1').textContent = forceAtL1.toFixed(2);\n document.getElementById('forceAtL1Result').style.display = 'block';\n }\n\n \/\/ Display Deflection (L)\n document.getElementById('deflection').textContent = calculatedDeflection.toFixed(2);\n document.getElementById('deflectionResult').style.display = 'block';\n\n \/\/ Calculate Spring Index (C)\n const springIndex = D \/ d;\n document.getElementById('springIndex').textContent = springIndex.toFixed(2);\n\n \/\/ Display Total Coils (Nt)\n document.getElementById('totalCoils').textContent = totalCoils.toFixed(1); \/\/ Assuming totalCoils was calculated earlier\n\n \/\/ Calculate Wahl Factor (A common stress correction factor)\n \/\/ Formula: Kw = (4C - 1) \/ (4C - 4) + 0.615 \/ C\n const wahlFactor = (4 * springIndex - 1) \/ (4 * springIndex - 4) + 0.615 \/ springIndex;\n document.getElementById('wahlFactor').textContent = wahlFactor.toFixed(3);\n\n\n \/\/ Show results section\n document.getElementById('results').classList.add('active');\n });\n <\/script>\n<\/body>\n<\/html>","protected":false},"excerpt":{"rendered":"<p>Discover the ultimate Compression Spring Design Calculator, your go-to tool for precise spring specifications and optimization. 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Descubra la Calculadora de Dise\u00f1o de Resortes de Compresi\u00f3n definitiva, su herramienta ideal para especificaciones y optimizaci\u00f3n precisas de resortes. Esta completa calculadora permite a ingenieros y dise\u00f1adores introducir par\u00e1metros clave y obtener resultados detallados para el dise\u00f1o de resortes de compresi\u00f3n, garantizando un alto rendimiento y fiabilidad. Con funciones intuitivas y c\u00e1lculos precisos, agilice su proceso de dise\u00f1o y consiga la funcionalidad \u00f3ptima de sus resortes. Perfecta para una gran variedad de aplicaciones, nuestra calculadora le ayuda a mejorar la eficiencia y reducir los errores de dise\u00f1o. Pru\u00e9bela ahora y revolucione su enfoque en el dise\u00f1o de resortes.<\/p>\n\n\n