Surge Protection Device - F-Type, Male to Female
Product Code: PROSPD11F
- Easy installation
- Brass metal casing
- Strong protection and high reliability
- High discharge capability
- IP20 rated
Product Description
Coaxial F-Type Surge Protection Device
Our coaxial F-Type SPD shields your aerial system's devices from power surges. Equipment such as TVs, amplifiers, and receiver boxes would benefit from having this line of defence.
What is a Surge Protection Device (SPD)?
Surge Protective Devices (SPD) are used to protect installations from electrical power surges known as “transient overvoltages”.
They are also used to protect sensitive electronic equipment connected to the installation, such as computers, televisions. Any equipment with sensitive electronic circuitry can be vulnerable to damage by transient overvoltages.
The effects of a surge can result in either instant failure or damage to the equipment only evident over a longer period of time. It is important to remember that protecting the electrical installation alone, and not the other services, could leave another route for transient voltages to enter the installation.
There are three different types of Surge Protective Devices:
Type 1 SPD: installed at the origin, e.g. main distribution board.
Type 2 SPD: installed at sub-level.
Type 3 SPD: installed close to the protected load. They must only be installed as a supplement to Type 2 SPD.
The PROception range of SPDs are all Type 2.
What causes transient overvoltages?
Natural transient overvoltages mostly occur due to direct lightning strikes but can also occur from indirect strikes too.
Man-made transients appear due to the switching of motors and transformers, along with some types of lighting. Historically this has not been an issue within domestic installations but more recently, installations are changing with the advent of electric vehicle charging, heat pumps have made transients much more likely to occur within domestic installations.
How do SPDs work?
The gas discharge tube (GDT) is sealed with ceramic and its interior consists of two or more metal electrodes with gaps filled with the inert gases, argon and neon. As the overvoltage passes through, it arcs between the electrodes, allowing current to flow to ground, thus protecting your devices.
Technical Information:
Electrical Characteristics | ||||||
Product Code | PROSPD11F | |||||
Connection Type | F-Type | |||||
Interface Type | Male to Female | |||||
Gas Discharge Tube Arrester | 90V/230V/350V | |||||
Frequency Range | DC - 1GHz | |||||
Operating Current | None | |||||
Max. Discharge Current (8/20μs) (Imax) | 10KA | |||||
Insertion Loss | <0.2dB | |||||
Insulation Resistance | ≥1000MΩ | |||||
Impedance | 75Ω | |||||
Input Power | <20W | <50W | <100W | <200W | <400W | <500W |
Initial Discharge Voltage | ≥50V | ≥70V | ≥120V | ≥190V | ≥280V | ≥280V |
Protection Mode(s) | Common Mode |
Mechanical Characteristics | ||||||
Technology | Gas Discharge Tube (GDT) | |||||
Connection to Network | Connector Male to Female | |||||
Mounting | Feedthrough | |||||
Housing Material | Brass HPb59-1 GB4425-84 | |||||
Working Temperature (°C) | -40 to 85 | |||||
Degree of Protection | IP20 | |||||
Failsafe Mode | Short-Circuit | |||||
Disconnection Indicator | Transmission Interrupt |
Technical Specification
Number of Outputs
1
IEC or F Type
F-Type
Width
30mm
Depth
30mm
Height
70mm
Weight
0.17kg
25/02/2025
11/02/2025
Amazingly quick de.ivery. Ordered at the weekend , arrived on Monday !
09/02/2025
Product as described and arrived on time, kept informed on progress throughout
04/02/2025
Somewhat confusing with the emails I received not identifying Blake UK as the sender easily
04/02/2025
Quick service and Quick delivery
Google Company Reviews
08/03/2025
Prompt delivery, hassle free purchase. I would use this company again.
02/03/2025
very good service
27/02/2025
Fantastic customer service - Thanks
17/02/2025
Cheapest on the net and received within in two days
14/02/2025
Great product and good service nice to find what you need
I’m pleased with the ærial overall. I did have to fix two separate issues though… 1. Many of the elements were bent, some quite badly. Happily they all bent straight again without any fatigue fracture. 2. Many of the elements were not seated properly in the booms. In one case, a vertical element was touching one on the other boom. I was able to pull the unseated ones out to seat better but I’m not sure how long they’ll stay like this.