Fiber Jumper

Your Professional Fiber Jumper Supplier

 

Ningbo Qimante Communication Technology Co., Ltd. is a Chinese fiber optic communication equipment manufacturer with 5 years of experience. Since its establishment in 2019, the company has produced 20 injection molding machines, complete supporting equipment in the sheet metal workshop, 4 laser cutting machines, a separate electrostatic spraying workshop, 4 fiber tail production lines, 25 PLC alignment machines, 4 production assembly lines, and 200 technical innovation personnel and assembly employees to meet customer needs.

 

Why Choose Us

Production Equipment

The company currently has production equipment such as injection molding machines, automatic nut planting machines, sheet metal laser cutting machines, bending machines, automatic welding machines, PLC alignment machines, fiber optic testers, fiber optic grinders, etc.

Production Market

The company's products are mainly exported to Southeast Asia, Europe, America, South America, the Middle East, Central Asia, Africa and other countries worldwide.

 

 

Our Service

From product sales to customer use, the company will always provide good service, allowing customers to use and construct with peace of mind.

 

 

Main Products

Currently, the company mainly produces products such as fiber optic distribution boxes, fiber optic distribution boxes, fiber optic junction boxes, fiber optic splice boxes, ODF fiber optic terminal boxes, ODF fiber optic distribution frames, fiber optic cable fixing equipment, etc.

 

 

Specifications

 

 

Cable Parameters

Singlemode

OM1

OM2

OM3

OM4

Fiber Count

1 or 2

1 or 2

1 or 2

1 or 2

1 or 2

Jacket Rating

OFNR or ORNP

OFNR or ORNP

OFNR or ORNP

OFNR or ORNP

OFNR or ORNP

Jacket Diameter

2 mm or 3 mm

2 mm or 3 mm

2 mm or 3 mm

2 mm or 3 mm

2 mm or 3 mm

Jacket Color

Yellow

Orange

Orange

Aqua

Aqua

Standard

SM - G.652D

OM1

OM2

OM3 - 10G-150

OM4

Wavelength (nm)

1310/1550

850/1300

850/1300

850/1300

850/1300

Attenuation Coefficient (dB/km)

≤0.34 @ 1310nm
≤0.20 @ 1550nm

≤2.7 @ 850nm
≤0.6 @ 1300nm

≤2.5 @ 850nm
≤0.6 @ 1300nm

≤2.5 @ 850nm
≤0.8 @ 1300nm

≤2.5 @ 850nm
≤0.8 @ 1300nm

Bandwidth (Min) (MHz/km)

200 @ 850nm
500 @ 1300nm

500 @ 850nm
500 @ 1300nm

OFL Bandwidth (MHz/km)

≥700 @ 850nm
≥500 @ 1300nm

≥3500 @ 850nm
≥500 @ 1300nm

Effective Modal (MHz/km)

≥950 @ 850nm
≥500 @ 1300nm

≥4700 @ 850nm
≥500 @ 1300nm

 

Mechanical Characteristics

Singlemode

Multimode (OM1 - OM4)

Simplex
2mm Jacket

Tension (N)

Long Term - 60
Short Term - 100

Long Term - 60
Short Term - 100

Crush (N/10 cm)

Long Term - 100
Short Term - 500

Long Term - 100
Short Term - 500

Min. Bend Radius

Dynamic - 50 mm
Static - 30 mm

Dynamic - 50 mm
Static - 30 mm

Simplex
3mm Jacket

Tension (N)

Long Term - 80
Short Term - 150

Long Term - 80
Short Term - 150

Crush (N/10 cm)

Long Term - 100
Short Term - 500

Long Term - 100
Short Term - 500

Min. Bend Radius

Dynamic - 60 mm
Static - 30 mm

Dynamic - 60 mm
Static - 30 mm

Duplex
2mm Jacket

Tension (N)

Long Term - 80
Short Term - 150

Long Term - 90
Short Term - 150

Crush (N/10 cm)

Long Term - 100
Short Term - 500

Long Term - 200
Short Term - 1000

Min. Bend Radius

Dynamic - 50 mm
Static - 30 mm

Dynamic - 50 mm
Static - 30 mm

Duplex
3mm Jacket

Tension (N)

Long Term - 160
Short Term - 300

Long Term - 160
Short Term - 300

Crush (N/10 cm)

Long Term - 200
Short Term - 1000

Long Term - 200
Short Term - 1000

Min. Bend Radius

Dynamic - 60 mm
Static - 30 mm

Dynamic - 60 mm
Static - 30 mm

Storage Temperature

-20°C to +60°C

-20°C to +60°C

Operating Temperature

-20°C to +60°C

-20°C to +60°C

 

   

Duplex Boot Color

Simplex Boot Color

       

Cable Mode

Connectore

Connector Color

2 mm

3 mm

2 mm

3 mm

Polish

Insertion Loss

Return Loss

Singlemode

ST
SC
SC/APC
LC
LC/APC
FC
FC/APC

Metal
Blue
Green
Blue
Green
Metal
Metal

Blue/White
Blue/White
Blue/White
White*
White*
Black**
Green**

Blue/White
Blue/White
Blue/White
Blue/White
Blue/White
Black
Green

Blue
Blue
Blue
White
White
Black
Green

Blue
Blue
Blue
Blue
Blue
Black
Green

UPC
UPC
APC
UPC
APC
UPC
APC

≤ 0.30dB( 0.25dB↓)

≥ 50dB
≥ 50dB
≥ 60dB
≥ 50dB
≥ 60dB
≥ 50dB
≥ 60dB

OM1

ST
SC
LC
FC

Metal
Beige
Beige
Metal

Black/Red
Black/Red
Black/Red
Black**

Black/Red
Black/Red
Black/Red
Black

Black
Black
Black
Black

Black
Black
Black
Black

PC
PC
PC
PC

≤ 0.30dB( 0.2dB↓)




OM3

ST
SC
LC
FC

Metal
Beige
Beige
Metal

Black/Red
Black/Red
White*
Black**

Black/Red
Black/Red
Black/Red
Black

Black
Black*
White
Black

Black
Black
Black
Black

PC
PC
PC
PC

≤ 0.30dB( 0.2dB↓)




OM4

SC
LC
FC

Magenta
Magenta
Metal

Black/Red
White*
Black**

Black/Red
Black/Red
Black

Black
White
Black

Black
Black
Black

PC
PC
PC

≤ 0.30dB( 0.2dB↓)



 

Fiber Part Numbers

Singlemode

OM1

OM2

OM3

OM4

Simplex

2 mm Jacket

RLH-JSR2SM-**M

RLH-JSR2MM-**M

RLH-JSR2M5-**M

RLH-JSR2MX-**M

RLH-JSR2MC-**M

3 mm Jacket

RLH-JSR3SM-**M

RLH-JSR3MM-**M

RLH-JSR3M5-**M

RLH-JSR3MX-**M

RLH-JSR3MC-**M

Duplex

2 mm Jacket

RLH-JDR2SM-**M

RLH-JDR2MM-**M

RLH-JDR2M5-**M

RLH-JDR2MX-**M

RLH-JDR2MC-**M

3 mm Jacket

RLH-JDR3SM-**M

RLH-JDR3MM-**M

RLH-JDR3M5-**M

RLH-JDR3MX-**M

RLH-JDR3MC-**M

 

FC UPC Fiber Optic Jumper
Advantages of Fiber Jumper

* High-speed data transmission: Fiber optic patch cords use optical fiber as the transmission medium; compared to traditional copper patch cords, fiber optic patch cords have faster transmission speeds and can support higher capacity data transmission. This makes fiber optic patch cords the preferred solution for high-speed data transmission.
* Stability and Reliability: Fiber optic patch cords have high anti-jamming ability and anti-electromagnetic interference ability, which can avoid transmission interruption or failure caused by electromagnetic interference, voltage fluctuation, and other factors. This makes it capable of stable data transmission in complex electromagnetic environments.
* Suitable for various scenarios: Fiber optic patch cords are widely used in data centers, computer rooms, broadcasting and television, industrial automation, security surveillance, transportation, and other fields, which can provide reliable data transmission and signal transmission solutions.
* Save space and cost: Fiber optic patch cords have smaller diameter, which can transmit more data in the same space. In addition, fiber optic patch cords have a longer service life, which can reduce maintenance and replacement costs.
* Low insertion loss and repeatability: Fiber optic patch cords have low insertion loss and good repeatability when connected, ensuring high quality and stability of data transmission.
* Durable and Long-Lasting: Fiber optic patch cords use high quality fiber optic materials, wear resistant, corrosion resistant, long service life, an investment can be a long-term benefit.
* Easy to install: The interfaces of fiber optic patch cords are standardized, very easy to install, no need for professional knowledge, users can easily get started.

 

 

Types of Fiber Jumper

 
Single mode or multimode fiber patch cord

* Single mode fiber patch cable: Single mode fiber patch cable only supports one mode of a light signal. It is usually used to transfer high-speed data with low attenuation over a long distance. Single mode fiber can often be divided into two types: OS1 and OS2.
* Multimode fiber patch cable: Multimode fiber patch cable allows multiple modes of light to travel through the fiber core and it is more suitable for short-distance transmission within the building or office. Multimode fiber patch cables can be classified into OM1, OM2, OM3, OM4, and OM5. You can choose the correct one according to your need.

Simplex or duplex patch cord

* Simplex patch cord: A simplex patch cord only has a single fiber cable and one fiber connector at each end. It only allows the data to transmit in one direction and that’s not reversible. Simplex patch cords are generally used within the building, suitable for Ethernet switches or other devices.
* Duplex patch cord: A duplex patch cord features two strands of fiber optic cable and two fiber connectors on each end to send and receive data. Duplex patch cords are often used to connect high-speed network devices such as server systems and fiber optic switches.

 

Application Areas of Fiber Jumper
 

Fiber optic access network: Fiber optic patch cords are used to transmit optical signals from fiber optic cables to devices for high-speed data transmission. This is especially important in broadband access scenarios such as Fiber to the Home (FTTH), which provides users with a fast and stable network connection.


Data center and Network communications: In data center and network communication, fiber optic patch cords are used to achieve long-distance and high-speed fiber optic data transmission. In the data center, fiber optic patch cords connect servers, switches, and other core equipment to ensure efficient and accurate data transmission.


Local area network (LAN): Fiber optic patch cords are used to connect network devices such as routers, switches, etc. to achieve data transmission within the LAN. This type of connection improves the data transmission speed and the stability and reliability of the network within the LAN.


Fiber optic CATV: Fiber optic patch cords are also used to transmit TV signals, providing cable TV networks with higher definition TV programs. With the popularity of high-definition and ultra-high-definition television, fiber optic patch cords are more and more widely used in the CATV field.


Fiber optic communication system: Fiber optic patch cords play an important role in various fiber optic communication systems, such as fiber optic gyroscope, fiber optic sensors and so on. These systems rely on fiber optic patch cords to transmit and receive optical signals to perform a variety of complex communication tasks.

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SC UPC Fiber Optic Jumper Pigtail

Interdevice subsystems and Workspace subsystems: Inter-device subsystems use fiber-optic patch cords to connect to various network devices for data transmission and control; workspace subsystems are used to connect to computers, printers, and other terminal devices to achieve data transmission and sharing and improve efficiency.


Test equipment: In the testing and maintenance process of fiber optic communication system, fiber optic patch cords are used to simulate the actual network environment, test and troubleshoot the system.


Fiber optic data transmission: In scenarios where high-speed data transmission is required, such as large data centers, fiber optic patch cords are used to connect various devices such as servers, routers, switches, and so on.


Fiber optic sensors: In some special sensors, such as temperature sensors, pressure sensors, etc., fiber optic patch cords are used to transmit signals.


Security monitoring system: In security monitoring system, fiber optic patch cords can provide faster transmission speed to ensure the normal operation of the system.

 

 

Sales Market

 

 

The company's products are mainly exported to Southeast Asia, Europe, America, South America, the Middle East, Central Asia, Africa and other countries worldwide. Our products have received unanimous praise from countries around the world, and foreign friends and customers visit the factory for inspection and visits up to 20 times a year.

 

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FAQ

 
 

Q: What are the advantages of jumper wire?

A: By attaching a jumper wire on the circuit, it can be short-circuited and short-cut (jump) to the electric circuit. By placing the jumper wire on the circuit, it becomes possible to control the electricity, stop the operation of the circuit, and operate a circuit that does not operate with ordinary wiring.

Q: How is polarization maintained in polarization-maintaining fiber optic patch cables?

A: By introducing stress rods to apply stress and achieve stress euilibrium within the fiber, thus making the polarization changes during transmission controllable.
Polarization-maintaining fibers are designed to maintain internal stress balance within the fiber, keeping the birefringence effect unchanged and generating fixed fast and slow axes to ensure stable polarization during transmission. The commonly used method involves introducing symmetrically asymmetric stress into the fiber core by adding stress rods containing two improved glass components on both sides of the fiber core. Stress-induced polarization-maintaining fibers utilize the difference in thermal expansion coefficients between the embedded stress rods and the fiber core, generating thermal stress that leads to changes in the material's refractive index, thereby producing birefringence effects.

Q: Is the extinction ratio parameter of polarization-maintaining fiber optic patch cables the same as the extinction ratio of polarizers?

A: The definition of extinction ratio is the same, but polarization-maintaining fiber optic patch cables and polarizers serve different functions.
The extinction ratio of polarization-maintaining fiber optic patch cables refers to the reference value of the extinction ratio maintained by highly extinguished polarized light after transmission, which is generally lower than the incident light. Its function is to maintain the original characteristics. On the other hand, polarizers convert low extinction ratio light into polarized light with the same high extinction ratio as the polarizer, focusing more on optimization.

Q: When using polarization-maintaining fiber optic patch cables, does the polarization direction of the incident light have to align with the slow axis to maintain polarization?

A: No. Aligning the polarization direction of the incident light with either the fast or slow axis of the patch cable can achieve polarization maintenance, but there may be differences in transmission speed.

Q: What is the damage threshold of fiber optic patch cables?

A: The damage threshold depends on the usage scenario. The factors limiting the power usage of the fiber mainly come from the connectors.

Q: What type of signal does a fiber jumper carry?

A: Fiber optic jumpers or fiber patch cables are an essential part of fiber optic devices, which are utilized to make physical connections among various network devices. It is these cables that help transmit light signals that help in the transfer of information in the fiber optic system.

Q: Where does each jumper cable go?

A: Here's the correct order for your jumper cables: RED to DEAD: Connect the red clip to the positive terminal on your dead battery. RED to DONOR: Connect the red clip to the positive terminal on the donor vehicle's working battery. BLACK to DONOR: Same car!

Q: What are the most common fiber optic patch cables?

A: There are many common types of fiber patch cables and your network may require one or more of them to operate most efficiently. Professionals use several ways to categorize the most common fiber patch cables, including the fiber cable type, the termination connector types, the optical fiber modes, the size of the fiber cable, and the various styles of polishing the connectors.

Q: How are fiber optic patch cables terminated?

A: There are basically two ways to terminate a fiber cable: using the same connector type on both ends of the cable (e.g., LC to LC) and using two different connectors on each end of the cable (e.g., ST to SC) which is also known as a Hybrid termination.

Q: What Modes are used in optical fiber patch cables?

A: Currently, there are three different modes that are used in fiber patch cords: singlemode, multimode, and 10Gigabit multimode. Singlemode fiber cables rely on 9/125 (micron) fiber cable with singlemode connectors on each end of the cable. Multimode fiber optic patch cables use 62.5/125 micron or 50/125 micron fiber cabling and are terminated with multimode fiber optic connectors on each end of the cable. 10Gb multimode fiber optic patch cords use enhanced 50/125 micron fiber that is optimized for 850nm VCSEL (Vertical Cavity Surface Emitting Lasers) based 10Gb Ethernet. They are usually compatible with existing network equipment and can offer 300% more bandwidth than traditional 62.5/125 multimode fibers. These cables are also rated for distances up to 300 meters.

Q: What Sizes do fiber optic patch cables come in?

A: Generally, manufacturers produce the following sizes: 250um bare fiber, 900um tight buffer fiber, 1.6mm fiber optic cable, 2.0mm fiber optic cable, and 3.0mm fiber optic cable.

Q: Are there other more specialized forms of fiber optic patch cables?

A: Yes. For example there are mode conditioning fiber cords, polarization maintaining fiber cables, and pre-terminated pigtails. All of these have specialized usages in various network configurations.

Q: What are some other names for fiber optic patch cables?

A: This is by no means a comprehensive list of synonyms for these cables, but we have heard them called: fiber optic patch cords, fiber optic jumpers, fiber jumper cables, fiber jumpers, fiber optic jumpers, duplex fiber jumpers, fiber wire, lan fiber, network fiber, optic cables, network glass, and more.

We're professional fiber jumper manufacturers and suppliers in China, specialized in providing high quality customized service. We warmly welcome you to wholesale high-grade fiber jumper from our factory. SC UPC Fiber Optic Jumper Pigtail, SC APC Fiber Optic Jumper Pigtail, FC UPC Fiber Optic Jumper

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