Produktbeschreibung

Why Choose US

Company Introduction

Production Process

 

Product Overview

 

MODEL

INPUT

VOLTAGE

RATED POWER

(kW)

RATED INPUT

CURRENT

(A)

RATED OUTPUT

CURRENT

(A)

FU9000D-0R7G-S2

1PH 

220V-240V

0.75

8.2

4

FU9000D-1R5G-S2

 

1.5

14

7

FU9000D-2R2G-S2

 

2.2

23

9.6

FU9000D-0R7G-2

3PH 

220V-240V

0.75

4.5

4

FU9000D-1R5G-2

 

1.5

8

7

FU9000D-2R2G-2

 

2.2

11

10

FU9000D-004G-2

 

4

14.6

13

FU9000D-5R5G-2

 

5.5

26

25

FU9000D-7R5G-2

 

7.5

35

32

FU9000D-011G-2

 

11

46.5

45

FU9000D-015G-2

 

15

62

60

FU9000D-018G-2

 

18.5

76

75

FU9000D-571G-2

 

22

92

91

FU9000D-030G-2

 

30

113

112

FU9000D-037G-2

 

37

157

150

FU9000D-045G-2

 

45

180

176

FU9000D-055G-2

 

55

214

210

FU9000D-075G-2

 

75

307

304

FU9000D-0R7G-4

3PH 

380V-480V

0.75

3.4

2.5

FU9000D-1R5G-4

 

1.5

5

3.7

FU9000D-2R2G-4

 

2.2

5.8

5

FU9000D-004G-4

 

4.0

10.5

9

FU9000D-5R5G-4

 

5.5

14.6

13

FU9000D-7R5G-4

 

7.5

20.5

17

FU9000D-011G-4

 

11

26

25

FU9000D-015G-4

 

15

35

32

FU9000D-018G-4

 

18.5

38.5

37

FU9000D-571G-4

 

22

46.5

45

FU9000D-030G-4

 

30

62

60

FU9000D-037G-4

 

37

76

75

FU9000D-045G-4

 

45

92

91

FU9000D-055G-4

 

55

113

112

FU9000D-075G-4

 

75

157

150

FU9000D-090G-4

 

90

180

176

FU9000D-110G-4

 

110

214

210

FU9000D-132G-4

 

132

256

253

FU9000D-160G-4

 

160

307

304

FU9000D-185G-4

 

185

340

330

FU9000D-200G-4

 

200

385

377

FU9000D-220G-4

 

220

430

426

FU9000D-250G-4

 

250

468

465

FU9000D-280G-4

 

280

525

520

FU9000D-315G-4

 

315

590

585

FU9000D-350G-4

 

350

665

650

FU9000D-400G-4

 

400

785

725

FU9000D-500G-4

 

500

883

820

FU9000D-630G-4

 

630

1080

1000

Customer Feedback

Häufig gestellte Fragen

Q 1: What’s the function of USFULL VFD?

A: USFULL VFD control the speed and frequency of motors, which is widely used in industrial control, automation system and pump system.

Q 2: How to choose suitable VFD for my machine?

A: Please send us your machine details, we will provide you most suitable model type.

Q 3: What’s the payment term?

A: We accept T/T, L/C, D/A, D/P, WESTERN UNION, PAYPAL, CASH, etc.

Q 4: How you control quality?

A: Our inverters strictly follow ISO9001 quality control system. After 4 times quality inspect and high temperature testing we will print “QA” pass.

Q 5: What kind of certificate you have?

A: We have ISO, CE, CB, TUV, etc.

Send Inquiry

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Anwendung: Three Phase Transducer, Industry
Output Type: Triple
Principle of Work: Vector Control Transducer
Switch Mode: PWM Control
Main Circuit Type: Voltage
Voltage of Power Supply: Low Voltage Variable-Frequency Drive
Samples:
US$ 250/Piece
1 Piece(Min.Order)

|

Anpassung:
Verfügbar

|

Induktionsmotor

Können Sie das Konzept des Wirkungsgrads von Motoren erläutern und wie dieser mit Wechselstrommotoren zusammenhängt?

Der Wirkungsgrad eines Elektromotors ist ein Maß dafür, wie effektiv er elektrische Energie in mechanische Energie umwandelt. Er stellt das Verhältnis der nutzbaren Ausgangsleistung (mechanische Leistung) zur aufgenommenen Eingangsleistung (elektrische Leistung) dar. Ein höherer Wirkungsgrad bedeutet, dass der Motor einen größeren Anteil der elektrischen Energie in nutzbare mechanische Arbeit umwandelt und gleichzeitig Energieverluste in Form von Wärme und anderen Ineffizienzen minimiert.

Bei Wechselstrommotoren ist der Wirkungsgrad aufgrund ihrer vielfältigen Einsatzmöglichkeiten – von Haushaltsgeräten bis hin zu Industriemaschinen – besonders wichtig. Es gibt zwei Arten von Wechselstrommotoren: Induktionsmotoren, die am häufigsten vorkommen, und Synchronmotoren, die mit einer konstanten, an die Netzfrequenz angepassten Drehzahl laufen.

Der Wirkungsgrad eines Wechselstrommotors wird von mehreren Faktoren beeinflusst:

  1. Motorkonstruktion: Die Konstruktion des Motors, einschließlich seiner Kernmaterialien, Wicklungskonfiguration und Rotorkonstruktion, beeinflusst seinen Wirkungsgrad. Motoren mit niederohmigen Wicklungen, hochwertigen Magnetmaterialien und optimierten Rotorkonstruktionen weisen in der Regel einen höheren Wirkungsgrad auf.
  2. Motorgröße: Die physische Größe des Motors kann sich auch auf seinen Wirkungsgrad auswirken. Größere Motoren weisen im Allgemeinen einen höheren Wirkungsgrad auf, da sie Wärme besser ableiten und somit Verluste reduzieren können. Es ist jedoch wichtig, die Motorgröße an die Anwendungsanforderungen anzupassen, um einen Betrieb des Motors mit geringem Wirkungsgrad aufgrund von Unterlastung zu vermeiden.
  3. Betriebsbedingungen: Die Betriebsbedingungen, wie Lastbedarf, Drehzahl und Temperatur, beeinflussen den Wirkungsgrad von Motoren. Motoren sind typischerweise für maximale Effizienz bei oder nahe ihrer Nennlast ausgelegt. Der Betrieb des Motors über die Nennlast hinaus oder bei sehr geringer Last kann den Wirkungsgrad verringern. Auch hohe Umgebungstemperaturen können zu erhöhten Verlusten und einem geringeren Wirkungsgrad führen.
  4. Magnetische Verluste: Wechselstrommotoren weisen Verluste aufgrund magnetischer Effekte auf, wie beispielsweise Hysterese- und Wirbelstromverluste in den Kernmaterialien. Diese Verluste führen zu Wärmeentwicklung und verringern den Gesamtwirkungsgrad. Motorkonstruktionen, die magnetische Verluste durch den Einsatz hochwertiger Magnetmaterialien und optimierter Kernkonstruktionen minimieren, können den Wirkungsgrad verbessern.
  5. Mechanische Reibungs- und Windverluste: Reibungs- und Windverluste in den Lagern, der Welle und den rotierenden Teilen des Motors tragen ebenfalls zu Energieverlusten und einem geringeren Wirkungsgrad bei. Eine sachgemäße Schmierung, die richtige Lagerauswahl und die Reduzierung unnötigen mechanischen Widerstands können helfen, diese Verluste zu minimieren.

Die Effizienz ist ein wichtiger Faktor bei der Auswahl eines Wechselstrommotors, da sie sich direkt auf den Energieverbrauch und die Betriebskosten auswirkt. Motoren mit höherer Effizienz verbrauchen weniger Strom, was zu geringeren Energiekosten und einer kleineren Umweltbelastung führt. Darüber hinaus bedeutet eine höhere Effizienz oft eine geringere Wärmeentwicklung, was die Zuverlässigkeit und Lebensdauer des Motors erhöhen kann.

Regulierungsbehörden und Normungsorganisationen wie die Internationale Elektrotechnische Kommission (IEC) und die National Electrical Manufacturers Association (NEMA) legen Effizienzklassen und -standards für Wechselstrommotoren fest, beispielsweise die IE-Effizienzklassen und die NEMA-Premium-Effizienzstandards. Diese Standards helfen Verbrauchern, die Effizienz verschiedener Motoren zu vergleichen und fundierte Entscheidungen zur Optimierung der Energieeffizienz zu treffen.

Zusammenfassend lässt sich sagen, dass der Wirkungsgrad eines Motors angibt, wie effektiv ein Wechselstrommotor elektrische Energie in mechanische Energie umwandelt. Durch die Auswahl von Motoren mit höherem Wirkungsgrad können Anwender den Energieverbrauch, die Betriebskosten und die Umweltbelastung reduzieren und gleichzeitig einen zuverlässigen und nachhaltigen Motorbetrieb gewährleisten.

Induktionsmotor

What are the common signs of AC motor failure, and how can they be addressed?

AC motor failure can lead to disruptions in various industrial and commercial applications. Recognizing the common signs of motor failure is crucial for timely intervention and preventing further damage. Here are some typical signs of AC motor failure and potential ways to address them:

  • Excessive Heat: Excessive heat is a common indicator of motor failure. If a motor feels excessively hot to the touch or emits a burning smell, it could signify issues such as overloaded windings, poor ventilation, or bearing problems. To address this, first, ensure that the motor is properly sized for the application. Check for obstructions around the motor that may be impeding airflow and causing overheating. Clean or replace dirty or clogged ventilation systems. If the issue persists, consult a qualified technician to inspect the motor windings and bearings and make any necessary repairs or replacements.
  • Abnormal Noise or Vibration: Unusual noises or vibrations coming from an AC motor can indicate various problems. Excessive noise may be caused by loose or damaged components, misaligned shafts, or worn bearings. Excessive vibration can result from imbalanced rotors, misalignment, or worn-out motor parts. Addressing these issues involves inspecting and adjusting motor components, ensuring proper alignment, and replacing damaged or worn-out parts. Regular maintenance, including lubrication of bearings, can help prevent excessive noise and vibration and extend the motor’s lifespan.
  • Intermittent Operation: Intermittent motor operation, where the motor starts and stops unexpectedly or fails to start consistently, can be a sign of motor failure. This can be caused by issues such as faulty wiring connections, damaged or worn motor brushes, or problems with the motor’s control circuitry. Check for loose or damaged wiring connections and make any necessary repairs. Inspect and replace worn or damaged motor brushes. If the motor still exhibits intermittent operation, it may require professional troubleshooting and repair by a qualified technician.
  • Overheating or Tripping of Circuit Breakers: If an AC motor consistently causes circuit breakers to trip or if it repeatedly overheats, it indicates a problem that needs attention. Possible causes include high starting currents, excessive loads, or insulation breakdown. Verify that the motor is not overloaded and that the load is within the motor’s rated capacity. Check the motor’s insulation resistance to ensure it is within acceptable limits. If these measures do not resolve the issue, consult a professional to assess the motor and its electrical connections for any faults or insulation breakdown that may require repair or replacement.
  • Decreased Performance or Efficiency: A decline in motor performance or efficiency can be an indication of impending failure. This may manifest as reduced speed, decreased torque, increased energy consumption, or inadequate power output. Factors contributing to decreased performance can include worn bearings, damaged windings, or deteriorated insulation. Regular maintenance, including lubrication and cleaning, can help prevent these issues. If performance continues to decline, consult a qualified technician to inspect the motor and perform any necessary repairs or replacements.
  • Inoperative Motor: If an AC motor fails to operate entirely, there may be an issue with the power supply, control circuitry, or internal motor components. Check the power supply and connections for any faults or interruptions. Inspect control circuitry, such as motor starters or contactors, for any damage or malfunction. If no external faults are found, it may be necessary to dismantle the motor and inspect internal components, such as windings or brushes, for any faults or failures that require repair or replacement.

It’s important to note that motor failure causes can vary depending on factors such as motor type, operating conditions, and maintenance practices. Regular motor maintenance, including inspections, lubrication, and cleaning, is essential for early detection of potential failure signs and for addressing issues promptly. When in doubt, it is advisable to consult a qualified electrician, motor technician, or manufacturer’s guidelines for appropriate troubleshooting and repair procedures specific to the motor model and application.

Induktionsmotor

How does the speed control mechanism work in AC motors?

The speed control mechanism in AC motors varies depending on the type of motor. Here, we will discuss the speed control methods used in two common types of AC motors: induction motors and synchronous motors.

Speed Control in Induction Motors:

Induction motors are typically designed to operate at a constant speed determined by the frequency of the AC power supply and the number of motor poles. However, there are several methods for controlling the speed of induction motors:

  1. Varying the Frequency: By varying the frequency of the AC power supply, the speed of an induction motor can be adjusted. This method is known as variable frequency drive (VFD) control. VFDs convert the incoming AC power supply into a variable frequency and voltage output, allowing precise control of motor speed. This method is commonly used in industrial applications where speed control is crucial, such as conveyors, pumps, and fans.
  2. Changing the Number of Stator Poles: The speed of an induction motor is inversely proportional to the number of stator poles. By changing the connections of the stator windings or using a motor with a different pole configuration, the speed can be adjusted. However, this method is less commonly used and is typically employed in specialized applications.
  3. Adding External Resistance: In some cases, external resistance can be added to the rotor circuit of an induction motor to control its speed. This method, known as rotor resistance control, involves inserting resistors in series with the rotor windings. By varying the resistance, the rotor current and torque can be adjusted, resulting in speed control. However, this method is less efficient and is mainly used in specific applications where precise control is not required.

Speed Control in Synchronous Motors:

Synchronous motors offer more precise speed control compared to induction motors due to their inherent synchronous operation. The following methods are commonly used for speed control in synchronous motors:

  1. Adjusting the AC Power Frequency: Similar to induction motors, changing the frequency of the AC power supply can control the speed of synchronous motors. By adjusting the power frequency, the synchronous speed of the motor can be altered. This method is often used in applications where precise speed control is required, such as industrial machinery and processes.
  2. Using a Variable Frequency Drive: Variable frequency drives (VFDs) can also be used to control the speed of synchronous motors. By converting the incoming AC power supply into a variable frequency and voltage output, VFDs can adjust the motor speed with high accuracy and efficiency.
  3. DC Field Control: In some synchronous motors, the rotor field is supplied by a direct current (DC) source, allowing for precise control over the motor’s speed. By adjusting the DC field current, the magnetic field strength and speed of the motor can be controlled. This method is commonly used in applications that require fine-tuned speed control, such as industrial processes and high-performance machinery.

These methods provide different ways to control the speed of AC motors, allowing for flexibility and adaptability in various applications. The choice of speed control mechanism depends on factors such as the motor type, desired speed range, accuracy requirements, efficiency considerations, and cost constraints.

China OEM Usfull 0.75kw to 700kw 3phase/380V/400V/415V Frequency Inverter AC Motor with Vector Control   with high quality China OEM Usfull 0.75kw to 700kw 3phase/380V/400V/415V Frequency Inverter AC Motor with Vector Control   with high quality
editor by CX 2024-05-03