Calculadora de divisores de engranajes: soluciones profesionales de divisi\u00f3n de engranajes<\/title>\n <style>\n #my-gear-calculator *,\n #my-gear-calculator *::before,\n #my-gear-calculator *::after {\n margin: 0 !important;\n padding: 0 !important;\n box-sizing: border-box !important;\n }\n #my-gear-calculator {\n font-family: -apple-system, BlinkMacSystemFont, \"Segoe UI\", Roboto, Oxygen-Sans, Ubuntu, Cantarell, \"Helvetica Neue\", sans-serif !important;\n color: #333 !important;\n background: #f9f9f9 !important;\n padding: 0 !important;\n }\n #my-gear-calculator .calculator-container {\n background: #fff !important;\n border-radius: 8px !important;\n box-shadow: 0 2px 10px rgba(0,0,0,0.08) !important;\n padding: 20px !important;\n margin: 30px auto !important;\n max-width: 900px !important;\n }\n #my-gear-calculator .section {\n margin-bottom: 30px !important;\n }\n #my-gear-calculator h2 {\n color: #000 !important;\n margin-bottom: 15px !important;\n font-size: 1.5em !important;\n }\n #my-gear-calculator .parameter-list {\n display: grid !important;\n grid-template-columns: repeat(auto-fit, minmax(250px, 1fr)) !important;\n gap: 15px !important;\n margin-bottom: 20px !important;\n }\n #my-gear-calculator .parameter-item {\n background: #f8f9fa !important;\n padding: 10px !important;\n border-radius: 4px !important;\n font-size: 15px !important;\n }\n #my-gear-calculator .input-form {\n display: grid !important;\n gap: 15px !important;\n margin-bottom: 0 !important;\n }\n #my-gear-calculator .two-col-form {\n grid-template-columns: repeat(2, 1fr) !important;\n }\n #my-gear-calculator .input-group {\n display: flex !important;\n flex-direction: column !important;\n }\n #my-gear-calculator label {\n margin-bottom: 5px !important;\n font-weight: 500 !important;\n }\n #my-gear-calculator input, #my-gear-calculator select {\n padding: 8px !important;\n border: 1px solid #ddd !important;\n border-radius: 4px !important;\n font-size: 16px !important;\n }\n #my-gear-calculator .calculate-btn {\n background: #007bff !important;\n color: white !important;\n border: none !important;\n padding: 12px 24px !important;\n border-radius: 4px !important;\n cursor: pointer !important;\n font-size: 16px !important;\n transition: background 0.3s, color 0.3s !important;\n width: 200px !important;\n margin: 20px auto 0 auto !important;\n display: block !important;\n text-align: center !important;\n }\n #my-gear-calculator .calculate-btn:hover {\n background: #0056b3 !important;\n color: #fff !important;\n }\n #my-gear-calculator .results {\n display: none !important;\n background: #e9ecef !important;\n padding: 20px !important;\n border-radius: 4px !important;\n margin-top: 20px !important;\n }\n #my-gear-calculator .result-item {\n margin-bottom: 10px !important;\n font-size: 1.1em !important;\n }\n #my-gear-calculator .result-value {\n font-weight: bold !important;\n color: #007bff !important;\n }\n #my-gear-calculator .button-row {\n width: 100% !important;\n display: flex !important;\n justify-content: center !important;\n margin-top: 0 !important;\n }\n @media (max-width: 768px) {\n #my-gear-calculator .input-form, #my-gear-calculator .two-col-form {\n grid-template-columns: 1fr !important;\n }\n #my-gear-calculator .parameter-list {\n grid-template-columns: 1fr !important;\n }\n }\n <\/style>\n<\/head>\n<body>\n <div id=\"my-gear-calculator\">\n <div class=\"calculator-container\">\n \n <div class=\"section\">\n <h2>Explicaci\u00f3n de los par\u00e1metros<\/h2>\n <div class=\"parameter-list\">\n <div class=\"parameter-item\"><strong>N\u00famero de divisiones (N):<\/strong> N\u00famero de posiciones de indexaci\u00f3n para el plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Tiempo de indexaci\u00f3n por divisi\u00f3n (t1, s):<\/strong> Es hora de que la unidad complete un movimiento de indexaci\u00f3n.<\/div>\n <div class=\"parameter-item\"><strong>Tiempo de indexaci\u00f3n por divisi\u00f3n (t2, s):<\/strong> Tiempo total para un ciclo de indexaci\u00f3n.<\/div>\n <div class=\"parameter-item\"><strong>Velocidad del eje de entrada (n, rpm):<\/strong> Velocidad de rotaci\u00f3n del eje de entrada.<\/div>\n <div class=\"parameter-item\"><strong>Di\u00e1metro de engranaje grande (D2, mm):<\/strong> Di\u00e1metro del engranaje grande.<\/div>\n <div class=\"parameter-item\"><strong>Peso del engranaje grande (W2, kg):<\/strong> Peso del engranaje grande.<\/div>\n <div class=\"parameter-item\"><strong>Di\u00e1metro de engranaje peque\u00f1o (D1, mm):<\/strong> Di\u00e1metro del engranaje peque\u00f1o.<\/div>\n <div class=\"parameter-item\"><strong>Peso del engranaje peque\u00f1o (W1, kg):<\/strong> Peso del engranaje peque\u00f1o.<\/div>\n <div class=\"parameter-item\"><strong>Peso del accesorio (m1, kg):<\/strong> Peso de un solo accesorio.<\/div>\n <div class=\"parameter-item\"><strong>Peso de la pieza de trabajo (m2, kg):<\/strong> Peso de una sola pieza de trabajo.<\/div>\n <div class=\"parameter-item\"><strong>N\u00famero de partidos (N1):<\/strong> N\u00famero total de accesorios en el plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Radio del c\u00edrculo primitivo del accesorio (Re, mm):<\/strong> Distancia desde el centro hasta la posici\u00f3n del accesorio.<\/div>\n <div class=\"parameter-item\"><strong>Radio efectivo del soporte de la base del plato giratorio (Rf, mm):<\/strong> Radio de apoyo efectivo de la base del plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>\u00c1ngulo del perfil de leva (\u03b8, grados):<\/strong> \u00c1ngulo de leva para un ciclo de indexaci\u00f3n.<\/div>\n <div class=\"parameter-item\"><strong>Di\u00e1metro del plato giratorio (D, mm):<\/strong> Di\u00e1metro del plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Espesor del plato giratorio (Dh, mm):<\/strong> Espesor del plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Factor de seguridad (e):<\/strong> Factor de seguridad de dise\u00f1o.<\/div>\n <div class=\"parameter-item\"><strong>Coeficiente de fricci\u00f3n (\u03bc):<\/strong> Coeficiente de fricci\u00f3n entre partes m\u00f3viles.<\/div>\n <div class=\"parameter-item\"><strong>Eficiencia hipot\u00e9tica (\u03b7):<\/strong> Eficiencia mec\u00e1nica supuesta.<\/div>\n <div class=\"parameter-item\"><strong>Velocidad radial m\u00e1xima (Vm, m\/s):<\/strong> Velocidad radial m\u00e1xima del plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Velocidad axial m\u00e1xima (Am, m\/s):<\/strong> Velocidad axial m\u00e1xima del plato giratorio.<\/div>\n <div class=\"parameter-item\"><strong>Coeficiente de fuerza radial m\u00e1xima (Qm):<\/strong> Coeficiente m\u00e1ximo para el c\u00e1lculo de fuerza radial.<\/div>\n <\/div>\n <\/div>\n\n \n \n\n \n <div class=\"section\">\n <h2>Calculadora<\/h2>\n <form id=\"calculator-form\" class=\"input-form two-col-form\" action=\"\">\n <div class=\"input-group\">\n <label for=\"N\">N\u00famero de divisiones (N):<\/label>\n <input type=\"number\" id=\"N\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"t1\">Tiempo de indexaci\u00f3n por divisi\u00f3n (t1, s):<\/label>\n <input type=\"number\" id=\"t1\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"t2\">Tiempo de indexaci\u00f3n por divisi\u00f3n (t2, s):<\/label>\n <input type=\"number\" id=\"t2\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"n\">Velocidad del eje de entrada (n, rpm):<\/label>\n <input type=\"number\" id=\"n\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"D2\">Di\u00e1metro de engranaje grande (D2, mm):<\/label>\n <input type=\"number\" id=\"D2\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"W2\">Peso del engranaje grande (W2, kg):<\/label>\n <input type=\"number\" id=\"W2\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"D1\">Di\u00e1metro de engranaje peque\u00f1o (D1, mm):<\/label>\n <input type=\"number\" id=\"D1\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"W1\">Peso del engranaje peque\u00f1o (W1, kg):<\/label>\n <input type=\"number\" id=\"W1\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"m1\">Peso del accesorio (m1, kg):<\/label>\n <input type=\"number\" id=\"m1\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"m2\">Peso de la pieza de trabajo (m2, kg):<\/label>\n <input type=\"number\" id=\"m2\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"N1\">N\u00famero de partidos (N1):<\/label>\n <input type=\"number\" id=\"N1\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Re\">Radio del c\u00edrculo primitivo del accesorio (Re, mm):<\/label>\n <input type=\"number\" id=\"Re\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Rf\">Radio efectivo del soporte de la base del plato giratorio (Rf, mm):<\/label>\n <input type=\"number\" id=\"Rf\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"theta\">\u00c1ngulo del perfil de leva (\u03b8, grados):<\/label>\n <input type=\"number\" id=\"theta\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"D\">Di\u00e1metro del plato giratorio (D, mm):<\/label>\n <input type=\"number\" id=\"D\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Dh\">Espesor del plato giratorio (Dh, mm):<\/label>\n <input type=\"number\" id=\"Dh\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"e\">Factor de seguridad (e):<\/label>\n <input type=\"number\" id=\"e\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"mu\">Coeficiente de fricci\u00f3n (\u03bc):<\/label>\n <input type=\"number\" id=\"mu\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"eta\">Eficiencia hipot\u00e9tica (\u03b7):<\/label>\n <input type=\"number\" id=\"eta\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Vm\">Velocidad radial m\u00e1xima (Vm, m\/s):<\/label>\n <input type=\"number\" id=\"Vm\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Am\">Velocidad axial m\u00e1xima (Am, m\/s):<\/label>\n <input type=\"number\" id=\"Am\" step=\"0.01\" required>\n <\/div>\n <div class=\"input-group\">\n <label for=\"Qm\">Coeficiente de fuerza radial m\u00e1xima (Qm):<\/label>\n <input type=\"number\" id=\"Qm\" step=\"0.01\" required>\n <\/div>\n <input type=\"hidden\" name=\"trp-form-language\" value=\"es\"\/><\/form>\n <div class=\"button-row\">\n <button type=\"submit\" form=\"calculator-form\" class=\"calculate-btn\">Calcule<\/button>\n <\/div>\n <\/div>\n\n \n <div id=\"results\" class=\"results\">\n <h2>Resultados de los c\u00e1lculos<\/h2>\n <div class=\"result-item\">\n Peso del plato giratorio (acero) (W3): <span class=\"result-value\" id=\"W3\">0<\/span> kg\n <\/div>\n <div class=\"result-item\">\n Peso total del accesorio (W4): <span class=\"result-value\" id=\"W4\">0<\/span> kg\n <\/div>\n <div class=\"result-item\">\n Peso total de la pieza de trabajo (W5): <span class=\"result-value\" id=\"W5\">0<\/span> kg\n <\/div>\n <div class=\"result-item\">\n Momento de inercia del engranaje peque\u00f1o (I1): <span class=\"result-value\" id=\"I1\">0<\/span> kg-m\n <\/div>\n <div class=\"result-item\">\n Gran momento de inercia del engranaje (I2): <span class=\"result-value\" id=\"I2\">0<\/span> kg-m\n <\/div>\n <div class=\"result-item\">\n Momento de inercia del plato giratorio (I3): <span class=\"result-value\" id=\"I3\">0<\/span> kg-m\n <\/div>\n <div class=\"result-item\">\n Momento de inercia de la fijaci\u00f3n (I4): <span class=\"result-value\" id=\"I4\">0<\/span> kg-m\n <\/div>\n <div class=\"result-item\">\n Momento de inercia de la pieza de trabajo (I5): <span class=\"result-value\" id=\"I5\">0<\/span> kg-m\n <\/div>\n <div class=\"result-item\">\n Aceleraci\u00f3n angular m\u00e1xima del eje de salida (\u03b11): <span class=\"result-value\" id=\"alpha1\">0<\/span> rad\/s\u00b2\n <\/div>\n <div class=\"result-item\">\n Par est\u00e1tico (momento de inercia) (Ti): <span class=\"result-value\" id=\"Ti\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Momento de inercia de la mesa de trabajo (Ti2): <span class=\"result-value\" id=\"Ti2\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par de inercia de engranaje peque\u00f1o (Ti1): <span class=\"result-value\" id=\"Ti1\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par de fricci\u00f3n (Tf): <span class=\"result-value\" id=\"Tf\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par de trabajo (Tw): <span class=\"result-value\" id=\"Tw\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par de carga total (Tt): <span class=\"result-value\" id=\"Tt\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par de carga real (Te): <span class=\"result-value\" id=\"Te\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Par del eje de entrada (Tc): <span class=\"result-value\" id=\"Tc\">0<\/span> N-m\n <\/div>\n <div class=\"result-item\">\n Potencia requerida (P): <span class=\"result-value\" id=\"P\">0<\/span> kW\n <\/div>\n <\/div>\n <\/div>\n <\/div>\n\n <script>\n document.querySelector('#my-gear-calculator #calculator-form').addEventListener('submit', function(e) {\n e.preventDefault();\n \/\/ Get input values\n const N = parseFloat(document.querySelector('#my-gear-calculator #N').value);\n const t1 = parseFloat(document.querySelector('#my-gear-calculator #t1').value);\n const t2 = parseFloat(document.querySelector('#my-gear-calculator #t2').value);\n const n = parseFloat(document.querySelector('#my-gear-calculator #n').value);\n const D2 = parseFloat(document.querySelector('#my-gear-calculator #D2').value);\n const W2 = parseFloat(document.querySelector('#my-gear-calculator #W2').value);\n const D1 = parseFloat(document.querySelector('#my-gear-calculator #D1').value);\n const W1 = parseFloat(document.querySelector('#my-gear-calculator #W1').value);\n const m1 = parseFloat(document.querySelector('#my-gear-calculator #m1').value);\n const m2 = parseFloat(document.querySelector('#my-gear-calculator #m2').value);\n const N1 = parseFloat(document.querySelector('#my-gear-calculator #N1').value);\n const Re = parseFloat(document.querySelector('#my-gear-calculator #Re').value);\n const Rf = parseFloat(document.querySelector('#my-gear-calculator #Rf').value);\n const theta = parseFloat(document.querySelector('#my-gear-calculator #theta').value);\n const D = parseFloat(document.querySelector('#my-gear-calculator #D').value);\n const Dh = parseFloat(document.querySelector('#my-gear-calculator #Dh').value);\n const eVal = parseFloat(document.querySelector('#my-gear-calculator #e').value);\n const mu = parseFloat(document.querySelector('#my-gear-calculator #mu').value);\n const eta = parseFloat(document.querySelector('#my-gear-calculator #eta').value);\n const Vm = parseFloat(document.querySelector('#my-gear-calculator #Vm').value);\n const Am = parseFloat(document.querySelector('#my-gear-calculator #Am').value);\n const Qm = parseFloat(document.querySelector('#my-gear-calculator #Qm').value);\n\n \/\/ Constants\n const pi = Math.PI;\n const rho = 7850; \/\/ Steel density kg\/m^3\n const G = 9.8; \/\/ Gravity acceleration m\/s^2\n const fc = eVal; \/\/ Safety factor\n \/\/ The following are not defined in input, set as 1 or need clarification:\n const w = 1; \/\/ Placeholder for angular velocity or weight, need clarification\n const R = 1; \/\/ Placeholder for radius, need clarification\n const S = 1; \/\/ Placeholder for stroke or step, need clarification\n const Z = 1; \/\/ Placeholder for gear ratio, need clarification\n\n \/\/ Derived values\n const R1 = D1 \/ 2 \/ 1000; \/\/ Small gear radius in meters\n const R2 = D2 \/ 2 \/ 1000; \/\/ Large gear radius in meters\n const Dt = Dh; \/\/ Use thickness as height for volume calculation (if not, please clarify)\n\n \/\/ 1. Turntable Weight (Steel) (W3)\n const W3 = (Math.pow(D2, 2) * pi \/ 4 * Dt * rho) \/ 1000;\n \/\/ 2. Total Fixture Weight (W4)\n const W4 = m1 * N1;\n \/\/ 3. Total Workpiece Weight (W5)\n const W5 = m2 * N1;\n \/\/ 4. Small Gear Moment of Inertia (I1)\n const I1 = (W1 * Math.pow(R1, 2)) \/ (2 * G);\n \/\/ 5. Large Gear Moment of Inertia (I2)\n const I2 = (W2 * Math.pow(R2, 2)) \/ (2 * G);\n \/\/ 6. Turntable Moment of Inertia (I3)\n const I3 = (W3 * Math.pow(R2, 2)) \/ (2 * G);\n \/\/ 7. Fixture Moment of Inertia (I4)\n const I4 = (W4 * Math.pow(Re \/ 1000, 2)) \/ G;\n \/\/ 8. Workpiece Moment of Inertia (I5)\n const I5 = (W5 * Math.pow(Re \/ 1000, 2)) \/ G;\n \/\/ 9. Output Shaft Maximum Angular Acceleration (\u03b11)\n const alpha1 = 72 * pi * Am * Math.pow(N, 2) \/ (S * Math.pow(theta \/ m1, 2));\n \/\/ 10. Static Torque (Moment of Inertia Torque) (Ti)\n \/\/ Ti = Ti1 + Ti2 (see below)\n \/\/ 11. Worktable Moment of Inertia Torque (Ti2)\n \/\/ \u03b12 is not defined, use alpha1 as placeholder\n const alpha2 = alpha1;\n const Ti2 = (I2 + I3 + I4 + I5) * Math.pow(N \/ N1, 2) * alpha2 * (N1 \/ N);\n \/\/ 12. Small Gear Moment of Inertia Torque (Ti1)\n const Ti1 = I1 * alpha1;\n \/\/ 13. Friction Torque (Tf)\n const Tf = mu * w * R * (N \/ N1);\n \/\/ 14. Working Torque (Tw) = 0\n const Tw = 0;\n \/\/ 15. Total Load Torque (Tt)\n const Ti = Ti1 + Ti2;\n const Tt = Ti + Tf + Tw;\n \/\/ 16. Actual Load Torque (Te)\n const Te = Tt * fc;\n \/\/ 17. Input Shaft Torque (Tc)\n const Tc = 360 \/ (S * theta) * Qm * Te;\n \/\/ 18. Required Power (P)\n const P = (Tc * n) \/ (975 * Z);\n\n \/\/ Display results\n document.querySelector('#my-gear-calculator #W3').textContent = W3.toFixed(2);\n document.querySelector('#my-gear-calculator #W4').textContent = W4.toFixed(2);\n document.querySelector('#my-gear-calculator #W5').textContent = W5.toFixed(2);\n document.querySelector('#my-gear-calculator #I1').textContent = I1.toExponential(3);\n document.querySelector('#my-gear-calculator #I2').textContent = I2.toExponential(3);\n document.querySelector('#my-gear-calculator #I3').textContent = I3.toExponential(3);\n document.querySelector('#my-gear-calculator #I4').textContent = I4.toExponential(3);\n document.querySelector('#my-gear-calculator #I5').textContent = I5.toExponential(3);\n document.querySelector('#my-gear-calculator #alpha1').textContent = alpha1.toExponential(3);\n document.querySelector('#my-gear-calculator #Ti').textContent = Ti.toFixed(2);\n document.querySelector('#my-gear-calculator #Ti2').textContent = Ti2.toFixed(2);\n document.querySelector('#my-gear-calculator #Ti1').textContent = Ti1.toFixed(2);\n document.querySelector('#my-gear-calculator #Tf').textContent = Tf.toFixed(2);\n document.querySelector('#my-gear-calculator #Tw').textContent = Tw.toFixed(2);\n document.querySelector('#my-gear-calculator #Tt').textContent = Tt.toFixed(2);\n document.querySelector('#my-gear-calculator #Te').textContent = Te.toFixed(2);\n document.querySelector('#my-gear-calculator #Tc').textContent = Tc.toFixed(2);\n document.querySelector('#my-gear-calculator #P').textContent = P.toExponential(3);\n\n \/\/ Show results section\n document.querySelector('#my-gear-calculator #results').style.display = 'block';\n });\n <\/script>\n<\/body>\n<\/html>","protected":false},"excerpt":{"rendered":"<p>Discover the precision and efficiency of our Rotary Index Table Calculator, designed to enhance your industrial machining processes. 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Descubra la precisi\u00f3n y eficiencia de nuestra Calculadora de Mesa Indexable Rotativa, dise\u00f1ada para optimizar sus procesos de mecanizado industrial. Esta innovadora herramienta ayuda a ingenieros y t\u00e9cnicos a calcular el posicionamiento rotacional preciso, mejorando la precisi\u00f3n de producci\u00f3n y reduciendo el tiempo de configuraci\u00f3n. Su interfaz intuitiva garantiza una integraci\u00f3n perfecta en su flujo de trabajo, mientras que sus robustos algoritmos ofrecen resultados fiables para diversas aplicaciones. Optimice sus operaciones con este recurso esencial, dise\u00f1ado para satisfacer las exigencias de la ingenier\u00eda moderna. Experimente la comodidad y precisi\u00f3n que la Calculadora de Mesa Indexable Rotativa aporta a sus proyectos hoy mismo.<\/p>\n\n\n