Catalogs > Industrial Controls Catalog > Relays, Timers, and Temperature Controllers > General Purpose Relays > Bulletin 700-HA Tube Base Relay
Bulletin 700-HA Tube Base Relay
| Introduction |  |
Standards Compliance and Certifications | |
Product Selection | |
Accessories | |
Specifications | |
Approximate Dimensions | |
| Cat. No. 700-HA… | ||||
| Electrical Ratings | ||||
| Pilot Duty RatingT | NEMA B300 | |||
| Rated Thermal Current (Ith) |
HA = 10 A – 120V, 240V HAB/HAX = 6 A – 120V, 240V |
|||
| Rated Insulation Voltage (Ui) | 250V IEC – 300V UL/CSA | |||
| Contacts | Inductive | Make | Break | Hp |
|
|
|||
| 120V AC | 30 A | 3 A | 1/3 | |
| 240V AC | 15 A | 1.5 A | 1 | |
| General Purpose | 10 A, 240V AC | |||
| Resistive | 10 A, 30V DC | |||
| Min. Low Energy Permissible Load | HA = 10V, 5 mA HAB= 5V, 5 mA HAX = 5V, 2 mA |
|||
| Permissible Coil Voltage Variation | Pickup: 80…110% of Nominal Voltage at 50 Hz 80…110% of Nominal Voltage at 60 Hz 80…110% of Nominal Voltage at DC |
|||
| Coil Consumption ±10% | AC Coils | 50 Hz | 60 Hz | |
| Inrush | 3.3 VA | 2.85 VA | ||
| Sealed | 2.2 VA | 1.9 VA | ||
| DC Coils | 1.3 W | |||
| Must Dropout Voltage | 20% of nominal V AC | |||
| 10% of nominal V DC | ||||
| Max. Contact Resistance | 50 MW (700-HA and 700-HAB) 30 MW (700-HAX) |
|||
| Design Specification/Test Requirements | ||||
| Electrical | ||||
| Pole-to-Pole | 1000V | |||
| Contact to Coil | 3600V | |||
| Contact to Frame | 4000V | |||
| Electrical Life (Operating) | 100 000 min. | |||
| Mechanical | ||||
| Degree of Protection (Open Type) IEC 529 |
IP 40 | |||
| Mechanical Life Cycles (AC/DC) | > 20 x 106/ 50 x 106 | |||
| Switching Frequency Operations | 3600/HR | |||
| Coil Voltages | See Product Selection | |||
| Operating Time | Max. Pickup | 10 ms | ||
| Max. Dropout | 10 ms | |||
| Maximum Operating Rate | 4 Ops/s | |||
| Vibration | Endurance | 5 G | ||
| Operational | 2.5 G | |||
| Shock | Endurance | 50 G | ||
| Operational | 9 G | |||
| Environmental | ||||
| Temperature | Operating | AC/DC | –40…+70 °C | |
| Storage | AC/DC | –40…+100 °C | ||
| Altitude | 2000 m (6560 ft) | |||
| Construction | ||||
| Insulating Material | Molded High-Dielectric Material | |||
| Enclosure | Transparent Dust Cover | |||
| Contact Material | 700-HA: | 10 A– AgNi | ||
| 700-HAB: | 6 A–Bifurcated AgNi | |||
| 700-HAX: | 6 A–Bifurcated/Gold Plating AgNi | |||
| Terminal Markings on Socket | In accordance with EN50 0005 | |||
| Sockets | 8-Pin Socket — 700-HN100, -HN125, -HN204 11-Pin Socket — 700-HN101, -HN126, -HN205 |
|||
| Certifications | cURus Recognized (File No. E3125, Guide NLDX2/NLDX8), cULus Listed when used with Bulletin 700-HN sockets noted above (File No. E3125, Guide NLDX/NLDX7), CE Marked, CSA Certified, UR Certified (File 229473) | |||
| Standards | UL508, CSA C22.2 No. 14, EN 61810-1, EN 60255-23 | |||
| ¬ See Performance Data. | ||||
| T NEMA Rating Chart is in publication 700-SG003_-EN-P. | ||||
700-HA Relay Performance Graphs
|
| Contact life vs. AC1 load at 1,800 cycles/h | Breaking capacity for DC1 load at 1,800 cycles/h. | Load reduction factor vs. cos f |
| A = load applied to one contact B = load applied to two contacts in series C = load applied to three contacts in series |
||
| Time Module Cat. No. 700-HT3 | ||
| Electrical Ratings | ||
| Operating Voltage Range | 12…240V AC (50/60 Hz) 12…240V DC | |
| Power Consumption | 0.1 W (12V) 1.0 W (230V) |
|
| Mechanical | ||
| Degree of Protection of Input (B1) Terminal | IP 20 (Guarded Terminal) | |
| Input Terminal Wire Range | 1.0 x 0.2 mm2…2.5 mm2 (24 AWG…14 AWG) 2.0 x 0.2 mm2…1.5 mm2 (24 AWG…16 AWG) |
|
| Input Terminal Torque Range | 0.45…0.8 Nm (4…7 lb-in.) | |
| LED Indicator | Red | |
| Repeat AccuracyT | ±1% | |
| Recovery Time | <50 ms | |
| Selectable Timing Ranges | Three DIP switches, seven ranges (set from 5…100% of range): 1 s, 10 s, 100 s, 10 min, 100 min, 10 h, 100 h |
|
| Selectable Timing Modes | Three DIP switches, eight modes: 1. Power On–Delay 2. Power On One-Shot 3. Power On Repeat Cycle, On Start 4. Signal On-Delay and Signal Off-Delay 5. Signal Off-Delay 6. Signal On-One-Shot 7. Signal Off-One-Shot 8. Signal On and Signal Off Watchdog Monitor |
|
| Adjustable Trimmer Scale Accuracy | ±5% of Time Range | |
| Environmental | ||
| Temperature | Operating | –20 °C…+50 °C (–4 °F…+122 °F) |
| Storage | –55 °C…+85 °C (–67…+185 °F) | |
| Altitude | 2000 m (6560 ft) | |
| Construction | ||
| Enclosure | Gray Plastic Housing | |
| Mounting with Socket Only | 8- or 11-Pin Socket with Module Plug | |
| Sockets | 700-HN204 (8-Pin with Plug) 700-HN205 (11-Pin with Plug) |
|
| Certifications | cURus Recognized (File No. E14843, Guide NRNT2/NRNT8), CE Marked | |
| Standards | UL508, CSA C22.2 No. 14, EN 61810-1, EN 60255-23 | |
| ¬ Performance Data - See this publication, ImportantPerformance Data. | ||
| T At constant voltage and temperature. | ||
Timing Charts, Cat. No. 700-HT3 Multi-Function Time Module (t = Time Range 0.05 s…100 h)
Terms:
U is Power Input
R is Relay Output
S Signal, +A1 Socket, B1 Timer
t is the resulting Time Delay (Red LED)
1. Power On-Delay
Apply power (U) to timer. Relay contacts (R) change state after time delay (t) is complete. Contacts return to their shelf state when power is removed. Terminal B1 is not used in this mode.
|
2. Power On One-Shot
Apply power (U) to timer. Relay contacts (R) change state immediately and the time delay begins. When the time delay (t) is complete, contacts return to their shelf state. Contacts return to their shelf state when power is removed. Terminal B1 is not used in this mode.
|
3. Power On Repeat Cycle, On Start
Apply power (U) to timer. Relay contacts (R) change state immediately and the time delay (t) begins. When the time delay is complete, the contacts return to their shelf state for time delay (t) (time on = time off). This cycle will repeat until the power is removed. Terminal B1 is not used in this mode.
|
4. Signal On-Delay and Signal Off-Delay
Apply power (U) to timer. When the signal (S) is closed the time delay (t) begins, after the time delay is complete the relay contacts (R) change state. Opening the signal starts the time delay, after the time delay is complete the contacts return to their shelf state. If the signal is closed or opened before the time delay is complete, the time delay is reset. Contacts return to their shelf state when power is removed.
|
Cat. No. 700-HT3 Timing Modes, Time Description, Timing Charts, and DIP Switch Selections
5. Signal Off-Delay
Apply power (U) to timer. When the signal (S) is closed, the relay contacts (R) change state immediately. When the signal is opened, the time delay (t) begins. If the signal is closed before the time delay is complete, the time delay is reset and the relay remains energized. When the time delay is complete, the contacts return to their shelf state. Contacts return to their shelf state when power is removed.
|
6. Signal On One-Shot
Apply power (U) to timer. When the signal (S) is closed, the relay contacts (R) change state immediately and the time delay (t) begins. After the time delay begins, opening or closing the signal will not reset the time delay. When the time delay is complete, the contacts return to their shelf state. Contacts return to their shelf state when power is removed.
|
7. Signal Off One-Shot
Apply power (U) to timer. When the signal (S) is closed and then opened, the relay contacts (R) change state immediately and the time delay (t) begins. After the time delay begins, opening or closing the signal will not reset the time delay. When the time delay is complete, the contacts return to their shelf state. Contacts return to their shelf state when power is removed.
|
8. Signal On and Signal Off Watchdog Monitor
Apply power (U) to timer. When the signal (S) is closed, the relay contacts (R) energize immediately and the time delay (t) begins. If the signal is opened before the time delay is complete, the relay remains energized and the time delay is reset. When the time delay is complete the contacts return to their shelf state. If the signal is opened after the time delay is complete, the relay contacts energize immediately and the same time delay begins. Continuous cycling of the signal at a rate that is faster than the time delay will cause the relay contacts to remain energized. Contacts return to their shelf state when power is removed.
|
