Name: 600T-IDW Series Medium Frequency DC Resistance Welding Controller
SKU: 2513933

Essential details

Quantity(pieces):1000

G.W:30 kg

Size:L(600)*W(500)*H(300) cm

N.W:26 kg

Shipping:land transportation, sea transportation

Specification Number:IDW-600T

Product Code:IDW-600T

Package Description:Wooden case packaging

Product Introduction

Advantages of Medium Frequency Inverter Resistance Welding Machine:

Comparison with Conventional Line-Frequency AC Welding Machines

Category Conventional Line-Frequency AC Welding Machine Medium-Frequency Inverter DC Controller
Performance Conventional line-frequency AC welding machines adjust the secondary output of the welding transformer by changing the thyristor firing angle. Since the transformer is directly connected to the grid via thyristors, the power factor is low. The adjustment cycle of line-frequency controllers is long (20 ms for 50/60 Hz grids). The medium-frequency inverter DC controller converts three-phase AC to DC, then outputs to the welding transformer via IGBT inversion. With a high power factor, its inverter frequency is 1 kHz, and adjustment time is as short as 1 ms – 20 times faster than conventional controllers. It offers higher control accuracy, faster response, and more stable output.
Power Grid The input voltage is single-phase 380V, causing two phases to draw high current and one phase to draw zero current. This unbalances the three-phase grid, leading to low grid utilization, high reactive power, and significant grid pollution. Multiple machines require large-capacity transformers, increasing customer costs. The input voltage is three-phase 380V, with balanced three-phase current and very high grid utilization. Using three-phase full-wave rectification, the power factor reaches over 90%.
Power Control Conventional controllers adjust welding current via thyristor firing angle. Current zero-crossing causes blank heating, poor heat concentration, and unstable welding quality. Long zero-crossing times worsen effects. Large grid voltage fluctuations cause current swings, severely impacting stability. Secondary circuit inductance also significantly affects welding current. The welding current is DC, with no zero-crossing. Heat is highly concentrated, heat loss is low, and welding time is shortened, resulting in significant energy savings. No AC peak values, so it is unaffected by grid fluctuations, reducing spatter and extending electrode life. Secondary circuit inductance has almost no effect on welding current, eliminating secondary loop losses.
Transformer Equipped with transformers operating at 50/60 Hz. At the same power rating, line-frequency transformers are large, bulky, lossy, and low-efficiency. Equipped with medium-frequency transformers operating at 1 kHz. At the same power rating, they are much smaller, with low losses, high efficiency, and easier installation.
Conclusion
In addition to the above advantages, medium-frequency inverter welding machines offer many more benefits, including a wide range of welding conditions, compatibility with various materials (medium-frequency machines can weld coated steels, galvanized steels, stainless steel, aluminum, and dissimilar metals), and combined welding characteristics, leading to widespread use in the industry.

1. Controller Features

Output power frequency: 1K-4K HZ, time precision at ms level
Programmable up to 32 sets of welding specifications
Three-stage heating process: preheating, welding, tempering; the welding stage allows custom ramp-up/ramp-down and cycle counts
Programmable output I/O ports: 3-stage programmable output for better compatibility with PLC, robots, etc.
Communication and BCD code control: connectable to industrial PC, PLC, etc., for remote control and automated management
Secondary coil feeds back welding current in real time for closed-loop control, ensuring precise current control
Alarm recording function for easy access to historical alarm information
Current control accuracy: 5‰

2.Basic Controller Parameters

IDW Series Medium Frequency DC Resistance Welding Controller
Inverter Mode
Medium Frequency DC
Model
DW400L IDW-600T IDW-800T IDW-100T IDW-1200T IDW-1800T IDW-2400
Input Voltage(V) Three-phase 380V, voltage fluctuation +10%, -20%; frequency 50HZ/60HZ±1%
Max Output Current(A) 400A 600A 900A 1100A 1300A 1800A 2400A
Matching Transformer
90KVA 120KVA 180KVA 200KVA 250KVA 350KVA 350*2KVA
Max Short-circuit Current(KA) 20KA 30KA 40KA 50KA 60KA 72KA 96KA
Air Switch Capacity
100A 100A 125A 160A 160A 200A 400A
Current Setting Range
0-400A/0-20KA 0-600A/0-30KA
0-900A/0-40KA
0-1000A/0-50KA
0-1300A/0-60KA
0-1800A/0-72KA
0-2400A/0-96KA
Control Method
Constant Current / Constant Conduction Angle
Number of Air Valves
Standard models are equipped with 4 air valves, while seam welding machines are equipped with 10 air valves.
Inverter Frequency
1K/4K HZ
Solenoid Valve Rated Output Voltage(V) DC24V±10%
Solenoid Valve Rated Output Current (A) ≤0.15A per channel
Communication Mode
Rs485
Maximum Welding Specification
32 groups, expandable to 256 groups
Cooling Water Requirement 6L/min, ≥0.15Mpa, temperature ≤40℃
8L/min, ≥0.15Mpa, temperature ≤40℃
12L/min, ≥0.15Mpa, temperature ≤40℃
Operating Temperature(℃) Water cooling -5℃~50℃
Ambient Humidity(%) ≤80%
Operating Altitude(Km) 1
Insulation Class Class F
Housing Dimensions (mm) Standard (customizable on request)

Operating Parameters

Parameter Description / Value
Start Signal Start Switch 1, Start Switch 2
Solenoid Valve Drive 3 Groups
Welding Program Storage 32 Sets
Pre-pressure Time (ms) 0-9999
Pressure Time (ms) 0-9999
Ramp-up Time (ms) 0-99
Preheat Time (ms) 0-999
Cooling Time (ms) 0-9999
Welding Time (ms) 0-999
Cooling Time (ms) 0-9999
Temper Time (ms) 0-999
Ramp-down Time (ms) 0-99
Hold Time (ms) 0-9999
Idle Time (ms) 0-9999
Current Control
Current 1 CC1 (Primary Constant Current) Primary Current 0-9999 (Unit: A)
CC2 (Secondary Constant Current) Secondary Current 0-99.99 (Unit: KA)
Current 2 CC1 (Primary Constant Current) Primary Current 0-9999 (Unit: A)
CC2 (Secondary Constant Current) Secondary Current 0-99.99 (Unit: KA)
Current 3 CC1 (Primary Constant Current) Primary Current 0-9999 (Unit: A)
CC2 (Secondary Constant Current) Secondary Current 0-99.99 (Unit: KA)

3.Controller Panel Description

7-inch industrial touch screen for parameter setting and function selection, real-time monitoring of welding current, capacitor voltage, etc. All operations can be completed on the touch screen.

4.Controller Operation Instructions

Display Introduction:After power-on, it automatically enters the Working Status screen; welding can only be performed in this screen.
Parameter setting screen: for welding parameter configuration
Function setting screen: single/continuous, seam welding, primary/secondary constant current, water flow/temp detection, dressing, cycle welding, etc.

Category	Conventional Line-Frequency AC Welding Machine	Medium-Frequency Inverter DC Controller
Performance	Conventional line-frequency AC welding machines adjust the secondary output of the welding transformer by changing the thyristor firing angle. Since the transformer is directly connected to the grid via thyristors, the power factor is low. The adjustment cycle of line-frequency controllers is long (20 ms for 50/60 Hz grids).	The medium-frequency inverter DC controller converts three-phase AC to DC, then outputs to the welding transformer via IGBT inversion. With a high power factor, its inverter frequency is 1 kHz, and adjustment time is as short as 1 ms – 20 times faster than conventional controllers. It offers higher control accuracy, faster response, and more stable output.
Power Grid	The input voltage is single-phase 380V, causing two phases to draw high current and one phase to draw zero current. This unbalances the three-phase grid, leading to low grid utilization, high reactive power, and significant grid pollution. Multiple machines require large-capacity transformers, increasing customer costs.	The input voltage is three-phase 380V, with balanced three-phase current and very high grid utilization. Using three-phase full-wave rectification, the power factor reaches over 90%.
Power Control	Conventional controllers adjust welding current via thyristor firing angle. Current zero-crossing causes blank heating, poor heat concentration, and unstable welding quality. Long zero-crossing times worsen effects. Large grid voltage fluctuations cause current swings, severely impacting stability. Secondary circuit inductance also significantly affects welding current.	The welding current is DC, with no zero-crossing. Heat is highly concentrated, heat loss is low, and welding time is shortened, resulting in significant energy savings. No AC peak values, so it is unaffected by grid fluctuations, reducing spatter and extending electrode life. Secondary circuit inductance has almost no effect on welding current, eliminating secondary loop losses.
Transformer	Equipped with transformers operating at 50/60 Hz. At the same power rating, line-frequency transformers are large, bulky, lossy, and low-efficiency.	Equipped with medium-frequency transformers operating at 1 kHz. At the same power rating, they are much smaller, with low losses, high efficiency, and easier installation.

Inverter Mode	Medium Frequency DC
Model	DW400L	IDW-600T	IDW-800T	IDW-100T	IDW-1200T	IDW-1800T	IDW-2400
Input Voltage(V)	Three-phase 380V, voltage fluctuation +10%, -20%; frequency 50HZ/60HZ±1%
Max Output Current(A)	400A	600A	900A	1100A	1300A	1800A	2400A
Matching Transformer	90KVA	120KVA	180KVA	200KVA	250KVA	350KVA	350*2KVA
Max Short-circuit Current(KA)	20KA	30KA	40KA	50KA	60KA	72KA	96KA
Air Switch Capacity	100A	100A	125A	160A	160A	200A	400A
Current Setting Range	0-400A/0-20KA	0-600A/0-30KA	0-900A/0-40KA	0-1000A/0-50KA	0-1300A/0-60KA	0-1800A/0-72KA	0-2400A/0-96KA
Control Method	Constant Current / Constant Conduction Angle
Number of Air Valves	Standard models are equipped with 4 air valves, while seam welding machines are equipped with 10 air valves.
Inverter Frequency	1K/4K HZ
Solenoid Valve Rated Output Voltage(V)	DC24V±10%
Solenoid Valve Rated Output Current (A)	≤0.15A per channel
Communication Mode	Rs485
Maximum Welding Specification	32 groups, expandable to 256 groups
Cooling Water Requirement	6L/min, ≥0.15Mpa, temperature ≤40℃		8L/min, ≥0.15Mpa, temperature ≤40℃		12L/min, ≥0.15Mpa, temperature ≤40℃
Operating Temperature(℃)	Water cooling -5℃~50℃
Ambient Humidity(%)	≤80%
Operating Altitude(Km)	1
Insulation Class	Class F
Housing Dimensions (mm)	Standard (customizable on request)

Parameter	Description / Value
Start Signal	Start Switch 1, Start Switch 2
Solenoid Valve Drive	3 Groups
Welding Program Storage	32 Sets
Pre-pressure Time (ms)	0-9999
Pressure Time (ms)	0-9999
Ramp-up Time (ms)	0-99
Preheat Time (ms)	0-999
Cooling Time (ms)	0-9999
Welding Time (ms)	0-999
Cooling Time (ms)	0-9999
Temper Time (ms)	0-999
Ramp-down Time (ms)	0-99
Hold Time (ms)	0-9999
Idle Time (ms)	0-9999
Current Control
Current 1	CC1 (Primary Constant Current)	Primary Current 0-9999 (Unit: A)
	CC2 (Secondary Constant Current)	Secondary Current 0-99.99 (Unit: KA)
Current 2	CC1 (Primary Constant Current)	Primary Current 0-9999 (Unit: A)
	CC2 (Secondary Constant Current)	Secondary Current 0-99.99 (Unit: KA)
Current 3	CC1 (Primary Constant Current)	Primary Current 0-9999 (Unit: A)
	CC2 (Secondary Constant Current)	Secondary Current 0-99.99 (Unit: KA)