Product Overview
The Y Safety Capacitance (Y) is designed for noise suppression in electronic equipment power circuits, as well as antenna coupling, bridging, and bypass circuits. It adheres to international safety standards, offering reliable performance for various electronic applications.
Product Attributes
- Brand: KNSCHA ()
- Product Name: Y Safety Capacitance
- Origin: Guangdong KNSCHA Electronics Co., Limited, China
- Encapsulation Material: Epoxy Resin
- Color: Blue
- Marking: Laser Printing
- Conforms to Standards: GB/T 2693-2001, GB/T 6346.14-2015, UL60384, IEC 60384-14, EN 60384-14
Technical Specifications
| Model/Part Number | Capacitance (pF) | Tolerance | Dielectric | Rated Voltage | Pitch (mm) | D (mm) | T max (mm) | F 0.8 (mm) | 0.05 (mm) | Packaging |
|---|---|---|---|---|---|---|---|---|---|---|
| Y5V103M300V20Y20003 | 10000 | 20% | Y5V | 300VAC | 7.5 | 13.0 | 4.0 | 7.5 | 0.6 | Bulk (B) |
Safety Certifications
| Country/Region | Certification Body | Standard Number | Certificate Number | Capacitance Range (pF) | Rated Voltage |
|---|---|---|---|---|---|
| USA/Canada | UL/CUL | UL60384 | E498213 | 10010000 | X1:400VAC, Y2:125VAC, Y2:250VAC, Y2:300VAC |
| Korea | KTL | K60384-14 | SU003107-19001 | 10010000 | Y2:300VAC |
| China | CQC | GB/T 6346.14-2015 | CQC19001218812 | 10010000 | Y2:300VAC |
| Germany | VDE | En 60384-14 | 40049793 | 10010000 | Y2:300VAC |
| EU | ENEC | En 60384-14 | 40049793 | 10010000 | Y2:300VAC |
| IEC | IEC-CB | IEC 60384-14 | DE1-61792 | 10010000 | Y2:300VAC |
Lead Type Specifications
| Lead Type | Part Number Suffix | Lead Length L (mm) | Encapsulated Lead Length C (mm) | Height H (mm) |
|---|---|---|---|---|
| Long Straight Leads | 1 | 16.0 min | C2.5mm (for product diameter <12mm) C3.0mm (for product diameter 12mm) | / |
| Short Straight Leads | 3 | 3.5 0.5 | C2.5mm (for product diameter <12mm) C3.0mm (for product diameter 12mm) | / |
| Single Outer Bend | 2 | 3.5 0.5 | Encapsulated lead not exceeding bend point, 5.0 Max. | / |
| Front and Back Warp | 8 | 3.5 0.5 | Encapsulated lead not exceeding bend point, 4.0 Max. | / |
Product Composition and Structure
| No. | Name | Material | Remarks |
|---|---|---|---|
| 1 | Electrode | Metal Layer | |
| 2 | Dielectric | Ceramic | |
| 3 | Solder | Tin Bar | |
| 4 | Metal Leads | CP Wire | |
| 5 | Encapsulation Material | Epoxy Resin | Color: Blue |
| 6 | Marking | Laser Printing |
Environmental Management Control Substances
| No. | Hazardous Substance Type | Hazardous Substance Name | Restricted Content |
|---|---|---|---|
| 1 | Heavy Metals | Cadmium and its compounds | <100ppm |
| Lead and lead compounds | <1000ppm | ||
| Mercury and mercury compounds | <1000ppm | ||
| Hexavalent chromium compounds | <1000ppm | ||
| 2 | Organic Bromides | Polybrominated biphenyls (PBB) | <1000ppm |
| Polybrominated diphenyl ethers (PBDE) including DecaBDE | <1000ppm | ||
| 3 | Halogens | Chlorine (Cl) | 900ppm |
| Bromine (Br) | 900ppm | ||
| Chlorine + Bromine (Cl+Br) | 1500ppm |
Notes
10.1 Storage and Usage Conditions
Do not store capacitors in corrosive gases, especially in environments containing chlorine, sulfur, acids, alkalis, or salts. Protect from moisture. Before cleaning, laminating, or sealing, test the performance of the product after these processes to ensure they do not affect product quality. Store capacitors in locations where temperature does not exceed 35 and relative humidity does not exceed 70%. Use within 1 year.
10.2 Operating Temperature and Self-Heating
The surface temperature of the capacitor should remain below the upper limit of its rated operating temperature range, considering self-generated heat. Self-heating may occur due to dielectric loss when used with high-frequency currents or surge currents. The frequency of the applied sine wave voltage should be below 300kHz. The applied voltage should ensure that self-heating and other loads do not exceed a 20 rise at an ambient temperature of 25. Measurement should be done using a thermocouple with low thermal capacity (K) of 0.1mm, and the capacitor should not be affected by heat dissipation from other components or ambient temperature fluctuations. Overheating may lead to a decrease in capacitor characteristics and reliability.
10.3 Soldering and Installation
10.3-1 Vibration and Shock
Avoid excessive shock or vibration to the capacitor or its leads during use.
10.3-2 Soldering
When soldering this product onto a PCB/PWB, do not exceed the capacitor's heat resistance specifications. Overheating can melt the internal solder, causing rapid temperature changes that may crack the ceramic element. When soldering with an iron, adhere to the following conditions: Soldering iron tip temperature: Max 400. Soldering iron power: Max 50W. Soldering time: Max 3.5 seconds.
10.3-3 Bonding, Resin Encapsulation, and Coating
Before bonding, encapsulating, or coating this product, test the performance of the product after these processes to ensure they do not affect capacitor quality. Improper application of adhesives, encapsulating resins, and organic solvents (containing components like ethyl acetate, methyl ethyl ketone, and toluene), as well as incorrect drying/curing states, can damage the capacitor's surface resin coating, leading to short circuits. Variations in the thickness of adhesives, encapsulating resins, and organic solvents can also cause cracks in the capacitor's surface resin coating and ceramic element during temperature cycling.
2504150952_KNSCHA-JY5V103M300V20Y20003_C2992590.pdf
Please Use Our Online Inquiry Contact Form Below If You Have Any Questions, Our Team Will Get Back To You As Soon As Possible
