Glass Glaze Film Resistor High Voltage Resistance 5W ...

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Glass Glaze Film Resistor High Voltage Resistance 5W 200M ohm 

High Performance and voltage Metal Glass Glaze Film Resistors can be used for and DC or impulse circuit and/or high-voltage apparatus. Suitable for Impulse voltage generators, Arc furnace damping, Energy research, Pulse modulators, Capacitor crowbar circuits, High voltage snubber circuits and EMI/lightning supression.

High Voltage Glaze Resistor from Savol is a type of functional high-voltage resistor, which is suitable for electronic circuits that are are designed to bear high voltage. It is called metal glazed leaded resistor , 
coat insulated megohm fixed resistor, high voltage and excellent surge performance.


Features: High Performance and voltage Metal Glass Glaze Film Resistors
1. Thick filming resulted in high surge-resist & stability
2. Operating ambient temperature: -55°C~+125°C.
3. High resistance value and working voltage.
4. Good high-frequency performance.
5. High precision, resistance tolerance: ±5%, ±10%.


Major Parameters: High Performance and voltage Metal Glass Glaze Film Resistors
1. Resistance Range:300Ω~200GΩ.
2. Rated Power:1/6W~10W.
3. Tolerance :±1%,±2%,±5% ,±10%.
4. Temperature coefficient:±200PPM/ºC.

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Main Resistors We Produce:

Items

Product Name

1

Carbon Film Fixed Resistors

2

Cement Resistors

3

Color Code Inductors

4

Gold Aluminum Housed Wirewound Resistors

5

High Power Ceramic Tube Wirewound Resistors

6

High Voltage Glaze Resistors

7

Ignition Resistor

8

Metal Film Fixed Resistors

9

Metal Film Fuse Resistors

10

Metal Oxide Film Fixed Resistors 

11

Metal Plate Noninductive Cement Resistors

12

Milliohm Resistors

13

Power Cabinet 

14

SMD MELF Resistors

15

SMD Shunt Resistor

16

SMD Wire Wound Round Resistor

17

TO-220 Power Resistor

18

Trapezium Aluminum Housed Wire-wound Resistors

19

Wirewound Fixed Resistors

20

Wirewound Fuse Resistors

 

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Company information

Company Profile

Established in ,Dongguan Savol Electronics co., LTD. is a manufacturer that specializing in R&D, Production and Sales of resistor products. 
Savol Electronics produces many series resistors, such as Carbon Film Fixed Resistors, Cement Resistors, Color Code  Inductors, Gold Aluminum Housed Wire wound Resistors, High Power Ceramic Tube Wire wound Resistors, High Voltage Glaze Resistors, Ignition Resistor, Metal Film Fixed Resistors, Metal Film Fuse Resistors, Metal Oxide Film Fixed Resistor, Metal Plate Non- inductive Cement Resistors, Milli ohm Resistors, Power Cabinet, SMD MELF Resistors, SMD Shunt Resistor, SMD Wire Wound Round Resistor, TO220 Power Resistor, Trapezium Aluminum Housed Wirewound Resistors, Wire Wound Fixed Resistors, Wire Wound Fuse Resistors, Braking Resistors ect.
Located in Shijie Town, the important town of Dongguan's electronics industry, China,  our factory is close to the railway station and subway, Shenzhen Yantian port and Hong Kong port as well.
Savol Electronics has passed ISO certification and the products strictly meet the ROHS standards. The resistors we produce are widely applied in Automotive Industry, Power Supply Industry,LED Lighting, Home Appliances, Communication Equipment, Toys, Medical Equipment Industry, Charging pile field Instrumentation Industries ect. Adhere to the purpose of technological innovation, integrity management, customer satisfaction, our products are sold worldwide and we have established good cooperative relations with many valuable clients, which have been cooperating with us for more than 15 years.

Our Service

Contact us to discuss your requirements of glass glaze resistor. Our experienced sales team can help you identify the options that best suit your needs.

FAQ

1. What about your product quality?

Our company had passed ISO certificates and with ROHS standards.

 

2. How long is the quality guarantee period?

Our quality can be assurance,One year warranty.

 

3.How about the MOQ/Minimum Order Quantity?

For your trial order ,MOQ can accept be ordered according to by MPQ or can be negotiate.Please contact us for more detail.

 

4.Can you provide samples?

We can provide samples, common specifications, if there is stock, we can also provide free samples, but the customer needs to pay the freight cost. For customized products, we need to charge a part of the fee. After customers place orders, we can return a part of the sample fee according to the situation.

 

5.How long is the delivery time?

Normally,3-7 working days after the payment received. For big bulk order, need be negotiate.2.How do you deliver the goods?

 

6.How do you deliver the goods? 

We can ship to you by UPS/DHL/TNT/EMS/FedEx/ by sea or others,Choose by clients. For the Countries & Regions where EMS cannot deliver, please choose other shipping ways. We are not responsible for any accidents, delays or other issues caused by the forwarder. Any import fees or charges are on the buyer's account. When orders or partial orders ship, an with the shipping details will be sent.

 

7.What are the ports near you?

HongKong port and YanTian port are near from us.

 

8.How to pay?

We accept  AliBaba Trade Assurance / Wire Transfer or T/T / Western Union / PayPal or can be negotiable if other payment method need. By the way, we won't change our payment account number halfway. Please confirm clear with our relevant personnel before arrange payment.

 

 

Q. I'd like to understand the differences between available resistor types and how to select the right one for a particular application.

A. Sure, let's talk first about the familiar 'discrete' or axial-­lead type resistors we're used to working with in the lab; then we'll compare cost and performance tradeoffs of the discretes and thin-­ or thick­-film networks.

Axial Lead Types: The three most common types of axial-­lead resistors we'll talk about are carbon composition, or carbon film, metal film and wirewound:

• carbon composition or carbon film­-type resistors are used in general­-purpose circuits where initial accuracy and stability with variations of temperature aren't deemed critical. Typical applications include their use as a collector or emitter load, in transistor/FET biasing networks, as a discharge path for charged capacitors, and as pull-­up and/or pull­-down elements in digital logic circuits.
  
  Carbon-­type resistors are assigned a series of standard values (Table 1) in a quasi­-logarithmic sequence, from 1 ohm to 22 megohms, with tolerances from 2% (carbon film) to 5% up to 20% (carbon composition). Power dissipation ratings range from 1/8 watt up to 2 watts. The 1/4­-watt and 1/2­-watt, 5% and 10% types tend to be the most popular.
  
  Carbon­-type resistors have a poor temperature coefficient (typically 5, 000 ppm/°C); so they are not well suited for precision applications requiring little resistance change over temperature, but they are inexpensive'­as little as 3 cents [USD 0.03] each in 1, 000 quantities.
  
  Table 1 lists a decade (10:1 range) of standard resistance values for 2% and 5% tolerances, spaced 10% apart. The smaller subset in lightface denote the only values available with 10% or 20% tolerances; they are spaced 20% apart.

Table 1. Standard resistor values: 2%, 5% and 10%

10 16 27 43 68 11 18 30 47 75 12 20 33 51 82 13 22 36 56 91 15 24 39 64 100

Carbon­-type resistors use color-­coded bands to identify the resistor's ohmic value and tolerance:

Table 2. Color code for carbon­-type resistors

digit color multiple # of zeroes tolerance '
silver 0.01 '2
10% '
gold 0.10 '1
5% 0 black 1 0 '
1 brown 10 1 '
2 red 100 2 2% 3 orange 1k 3 '
4 yellow 10k 4 '
5 green 100k 5 '
6 blue 1m 6 '
7 violet 10m 7 '
8 gray '
'
'
9 white '
'
'
'
none '
'
20%

• Metal film resistors are chosen for precision applications where initial accuracy, low temperature coefficient, and lower noise are required. Metal film resistors are generally composed of Nichrome, tin oxide or tantalum nitride, and are available in either a hermetically sealed or molded phenolic body. Typical applications include bridge circuits, RC oscillators and active filters. Initial accuracies range from 0.1 to 1.0 %, with temperature coefficients ranging between 10 and 100 ppm/°C. Standard values range from 10.0 ohms to 301 kohms in discrete increments of 2% (for 0.5% and 1% rated tolerances).

Table 3. Standard values for film­-type resistors

1.00 1.29 1.68 2.17 2.81 3.64 4.70 6.08 7.87 1.02 1.32 1.71 2.22 2.87 3.71 4.80 6.21 8.03 1.04 1.35 1.74 2.26 2.92 3.78 4.89 6.33 8.19 1.06 1.37 1.78 2.31 2.98 3.86 4.99 6.46 8.35 1.08 1.40 1.82 2.35 3.04 3.94 5.09 6.59 8.52 1.10 1.43 1.85 2.40 3.10 4.01 5.19 6.72 8.69 1.13 1.46 1.89 2.45 3.17 4.09 5.30 6.85 8.86 1.15 1.49 1.93 2.50 3.23 4.18 5.40 6.99 9.04 1.17 1.52 1.96 2.55 3.29 4.26 5.51 7.13 9.22 1.20 1.55 2.00 2.60 3.36 4.34 5.62 7.27 9.41 1.20 1.55 2.00 2.60 3.36 4.34 5.62 7.27 9.41 1.22 1.58 2.04 2.65 3.43 4.43 5.73 7.42 9.59 1.22 1.58 2.04 2.65 3.43 4.43 5.73 7.42 9.59 1.24 1.61 2.09 2.70 3.49 4.52 5.85 7.56 9.79 1.27 1.64 2.13 2.76 3.56 4.61 5.96 7.72 9.98

Metal film resistors use a 4 digit numbering sequence to identify the resistor value instead of the color band scheme used for carbon types:

• Wirewound precision resistors are extremely accurate and stable (0.05%, <10 ppm/°C); they are used in demanding applications, such as tuning networks and precision attenuator circuits. Typical resistance values run from 0.1 ohms to 1.2 Mohms.

High Frequency Effects: Unlike its 'ideal' counterpart, a 'real' resistor, like a real capacitor (Analog Dialogue 30­2), suffers from parasitics. (Actually, any two­-terminal element may look like a resistor, capacitor, inductor, or damped resonant circuit, depending on the frequency it's tested at.)

Factors such as resistor base material and the ratio of length to cross­-sectional area determine the extent to which the parasitic L and C affect the constancy of a resistor's effective dc resistance at high frequencies. Film type resistors generally have excellent high­-frequency response; the best maintain their accuracy to about 100 MHz. Carbon types are useful to about 1 MHz. Wirewound resistors have the highest inductance, and hence the poorest frequency response. Even if they are non-­inductively wound, they tend to have high capacitance and are likely to be unsuitable for use above 50 kHz.

Q. What about temperature effects? Should I always use resistors with the lowest temperature coefficients (TCRs)?

A. Not necessarily. A lot depends on the application. For the single resistor shown here, measuring current in a loop, the current produces a voltage across the resistor equal to I x R. In this application, the absolute accuracy of resistance at any temperature would be critical to the accuracy of the current measurement, so a resistor with a very low TC would be used.

A different example is the behavior of gain-­setting resistors in a gain­-of-100 op amp circuit, shown below. In this type of application, where gain accuracy depends on the ratio of resistances (a ratiometric configuration), resistance matching, and the tracking of the resistance temperature coefficients (TCRs), is more critical than absolute accuracy.

Here are a couple of examples that make the point.

1. Assume both resistors have an actual TC of 100 ppm/°C (i.e., 0.01%/°C). The resistance following a temperature change, ΔT, is

R = R0(1+ TC ΔT)

For a 10°C temperature rise, both RF and RI increase by 0.01%/°C x 10°C = 0.1%. Op amp gains are [to a very good approximation] 1 + RF/RI. Since both resistance values, though quite different (99:1), have increased by the same percentage, their ratio­ hence the gain ­is unchanged. Note that the gain accuracy depends just on the resistance ratio, independently of the absolute values.

2. Assume that RI has a TC of 100 ppm/°C, but RF's TC is only 75 ppm/°C. For a 10°C change, RI increases by 0.1% to 1.001 times its initial value, and RF increases by 0.075% to 1. times its initial value. The new value of gain is

(1. RF)/(1.001 RI) = 0. RF/RI

For an ambient temperature change of 10°C, the amplifier circuit's gain has decreased by 0.025% (equivalent to 1 LSB in a 12-­bit system). Another parameter that's not often understood is the self­-heating effect in a resistor.

Q. What's that?

A. Self­-heating causes a change in resistance because of the increase in temperature when the dissipated power increases. Most manufacturers' data sheets will include a specification called 'thermal resistance' or 'thermal derating', expressed in degrees C per watt (°C/W). For a 1/4­-watt resistor of typical size, the thermal resistance is about 125°C/W. Let's apply this to the example of the above op amp circuit for full-­scale input:

Power dissipated by RI is

E2/R = (100 mV)2/100 ohms = 100 µW, leading to a temperature change of 100 µW x 125°C/W = 0.°C, and a negligible 1­ppm resistance change (0.%).

Power dissipated by RF is

E2/R = (9.9 V)2/ ohms = 9.9 mW, leading to a temperature change of 0. W x 125°C/W = 1.24°C, and a resistance change of 0.%, which translates directly into a 0.012% gain change.

Thermocouple Effects: Wirewound precision resistors have another problem. The junction of the resistance wire and the resistor lead forms a thermocouple which has a thermoelectric EMF of 42 µV/°C for the standard 'Alloy 180'/Nichrome junction of an ordinary wirewound resistor. If a resistor is chosen with the [more expensive] copper/nichrome junction, the value is 2.5 µV/°C. ('Alloy 180' is the standard component lead alloy of 77% copper and 23% nickel.)

Such thermocouple effects are unimportant in ac applications, and they cancel out when both ends of the resistor are at the same temperature; however if one end is warmer than the other, either because of the power being dissipated in the resistor, or its location with respect to heat sources, the net thermoelectric EMF will introduce an erroneous dc voltage into the circuit. With an ordinary wirewound resistor, a temperature differential of only 4°C will introduce a dc error of 168 µV­ which is greater than 1 LSB in a 10­V/16­-bit system!

This problem can be fixed by mounting wirewound resistors so as to insure that temperature differentials are minimized. This may be done by keeping both leads of equal length, to equalize thermal conduction through them, by insuring that any airflow (whether forced or natural convection) is normal to the resistor body, and by taking care that both ends of the resistor are at the same thermal distance (i.e., receive equal heat flow) from any heat source on the PC board.

Q. What are the differences between 'thin-­film' and 'thick­-film' networks, and what are the advantages/disadvantages of using a resistor network over discrete parts?

A. Besides the obvious advantage of taking up considerably less real estate, resistor networks­'whether as a separate entity, or part of a monolithic IC­'­offer the advantages of high accuracy via laser trimming, tight TC matching, and good temperature tracking. Typical applications for discrete networks are in precision attenuators and gain setting stages. Thin film networks are also used in the design of monolithic (IC) and hybrid instrumentation amplifiers, and in CMOS D/A and A/D converters that employ an R­2R Ladder network topology.

Thick film resistors are the lowest­-cost type'they have fair matching (<0.1%), but poor TC performance (<100 ppm/°C) and tracking (<10 ppm/°C).They are produced by screening or electroplating the resistive element onto a substrate material, such as glass or ceramic.

Thin film networks are moderately priced and offer good matching (0.01%), plus good TC (<100 ppm/°C) and tracking (<10 ppm/°C). All are laser trimmable. Thin-film networks are manufactured using vapor deposition.

Table 4 compares the advantages/disadvantages of a thick film and several types of thin­-film resistor networks. Table 5 compares substrate materials.

Table 4. Resistor Networks
Type
Advantages
Disadvantages
Thick film
Low cost
Fair matching (0.1%)

High power
Poor TC (>100 ppm/°C)

Laser-trimmable
Poor tracking TC

Readily available
(10 ppm/°C)
Thin film on glass
Good matching (<0.01%)
Delicate

Good TC (<100 ppm/°C)
Often large geometry

Good tracking TC (2 ppm/°C)
Low power

Moderate cost


Laser-trimmable


Low capacitance

Thin film on ceramic
Good matching (<0.01%)
Often large geometry

Good TC (<100 ppm/°C)


Good tracking TC (2 ppm/°C)


Moderate cost


Laser-trimmable


Low capacitance

  Suitable for hybrid IC substrate

Thin film on silicon
Good matching (<0.01%)


Good TC (<100 ppm/°C)


Good tracking TC (2 ppm/°C)


Moderate cost


Laser-trimmable


Low capacitance


Suitable for hybrid IC substrate

Table 5. Substrate Materials

Substrate Advantages Disadvantages Glass
Low capacitance
Delicate
    Low power
    Large geometry
Ceramic
Low capacitance
Large geometry
  Suitable for hybrid IC substrate
  Silicon
Suitable for monolithic
Low power
  construction
Capacitance to substrate
Sapphire
Low capacitance
Low power
    Higher cost

In the example of the IC instrumentation amplifier shown below, tight matching between resistors R1­-R1', R2-­R2', R3-­R3' insures high common-­mode rejection (as much as 120 dB, dc to 60 Hz). While it is possible to achieve higher common-­mode rejection using discrete op amps and resistors, the arduous task of matching the resistor elements is undesirable in a production environment.

Matching, rather than absolute accuracy, is also important in R­2R ladder networks (including the feedback resistor) of the type used in CMOS D/A converters. To achieve n-­bit performance, the resistors have to be matched to within 1/2n, which is easily achieved through laser trimming. Absolute accuracy error, however, can be as much as ±20%. Shown here is a typical R­-2R ladder network used in a CMOS digital­ analog converter.

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