參數(shù)資料
型號(hào): W172DIP-147
英文描述: RELAY REED DIL 5VDC
中文描述: 勵(lì)迪勒5Vdc時(shí)繼電器
文件頁數(shù): 69/210頁
文件大?。?/td> 7067K
代理商: W172DIP-147
第1頁第2頁第3頁第4頁第5頁第6頁第7頁第8頁第9頁第10頁第11頁第12頁第13頁第14頁第15頁第16頁第17頁第18頁第19頁第20頁第21頁第22頁第23頁第24頁第25頁第26頁第27頁第28頁第29頁第30頁第31頁第32頁第33頁第34頁第35頁第36頁第37頁第38頁第39頁第40頁第41頁第42頁第43頁第44頁第45頁第46頁第47頁第48頁第49頁第50頁第51頁第52頁第53頁第54頁第55頁第56頁第57頁第58頁第59頁第60頁第61頁第62頁第63頁第64頁第65頁第66頁第67頁第68頁當(dāng)前第69頁第70頁第71頁第72頁第73頁第74頁第75頁第76頁第77頁第78頁第79頁第80頁第81頁第82頁第83頁第84頁第85頁第86頁第87頁第88頁第89頁第90頁第91頁第92頁第93頁第94頁第95頁第96頁第97頁第98頁第99頁第100頁第101頁第102頁第103頁第104頁第105頁第106頁第107頁第108頁第109頁第110頁第111頁第112頁第113頁第114頁第115頁第116頁第117頁第118頁第119頁第120頁第121頁第122頁第123頁第124頁第125頁第126頁第127頁第128頁第129頁第130頁第131頁第132頁第133頁第134頁第135頁第136頁第137頁第138頁第139頁第140頁第141頁第142頁第143頁第144頁第145頁第146頁第147頁第148頁第149頁第150頁第151頁第152頁第153頁第154頁第155頁第156頁第157頁第158頁第159頁第160頁第161頁第162頁第163頁第164頁第165頁第166頁第167頁第168頁第169頁第170頁第171頁第172頁第173頁第174頁第175頁第176頁第177頁第178頁第179頁第180頁第181頁第182頁第183頁第184頁第185頁第186頁第187頁第188頁第189頁第190頁第191頁第192頁第193頁第194頁第195頁第196頁第197頁第198頁第199頁第200頁第201頁第202頁第203頁第204頁第205頁第206頁第207頁第208頁第209頁第210頁
APPLICATION DATA
REED
RELAYS
ELECTRICAL CHARACTERISTICS (Continued)
RELEASE TIME (Continued)
If the relay coil is suppressed, release times are increased. Diode suppres-
sion can delay release times for several milliseconds, depending on coil
characteristics, coil voltage, and reed release characteristics.
CONTACT BOUNCE
Dry reed contacts bounce on closure as with any other hard contact relay.
The duration of bounce on a Dry reed switch is typically very short, and is
in part dependent on drive level. In some of the faster devices, the sum of
the operate time and bounce is relatively constant. As drive is increased, the
operate time decreases with bounce time increasing.
The normally closed contacts of a SPDT switch bounce more then the
normally open contacts. Magnetically biased SPST-NC contacts exhibit
essentially the same bounce characteristics as SPST-NO switches.
CONTACT RESISTANCE
The reeds (blades) in a dry reed switch are made of magnetic material
which has a high volume resistivity, terminal-to-terminal resistance is
somewhat higher than in some other types of relays. Typical specification
limits for initial resistance of a SPST-NO reed relay is 0.200 ohms max
(200 milliohms).
INSULATION RESISTANCE
A dry reed switch made in a properly controlled internal atmosphere will
have an insulation resistance of 10
12
to 10
13
ohms or greater. When it is
assembled into a relay, parallel insulation paths reduce this to typical values
of 10
9
ohms. Depending on the particular manner of relay construction,
exposure to high humidity or contaminating environments can appreciably
lower final insulation resistance.
CAPACITANCE.
Reed capsules typically have low terminal-to-terminal capacitance.
However, in the typicall relay structure where the switch is surrounded by a
coil, capacitance from each reed to the coil act to increase capacitance
many times. If the increased capacitance is objectionable, it can be
reduced by placing a grounded electrostatic shield between the switch and
coil.
DIELECTRIC WITHSTAND VOLTAGE
With the exception of the High-Voltage dry reed switches ( capsules that
are pressurized or evacuated), the dielectric strength limitation of relays is
determined by the ampere turn sensitivity of the switches used. A typical
limit is 200 VAC. The dielectric withstand voltage between switch and coil
terminals is usually 500 VAC.
THERMAL EMF
Since thermally generated voltages result from thermal gradients within the
relay assembly, relays built to minimize this effect often use sensitive
switches to reduce required coil power, and thermally conductive materials
to reduce temperature gradients. Latching relays, which may be operated
by a short duration pulse, are often used if the operational rate is not
changed for longer periods of time because coil power is not required to
keep the relay in the on or off position after the initial turn on or turn off
pulse.
NOISE
Noise is defined as a voltage appearing between terminals of a switch for a
few milliseconds following closure of the contacts. It occurs because the
reeds (blades) are moving in a magnetic field and because voltages are
produced within them by magnetostrictive effects. From an application
standpoint, noise is important if the signal switched by the reed is to be used
within a few milliseconds immediately following closure of the contacts.
When noise is critical in an application, a peak-to-peak limit must be
established by measurement techniques, including filters which must be
specified for that particular switching application.
ENVIRONMENTAL CHARACTERISTICS
Reed relays are used in essentially the same environments as other types of
relays. Factors influencing their ability to function would be
temperature extremes beyond specified limits
VIBRATION
The reed switch structure, with so few elements free to move, has a better
defined response to vibration than other relay types. With vibration inputs
reasonably separated from the resonant frequency, the reed relay will
withstand relatively high inputs, 20 g's or more. At resonance of the reeds,
the typical device can fail at very low input levels. Typical resonance
frequency is 2000 hz.
SHOCK
Dry reed relays will withstand relatively high levels of shock. SPST-NO
contacts are usually rated to pass 30 to 50 g's, 11 milliseconds, half sign
wave shock, without false operation of contacts. Switches exposed to a
magnetic field that keep the contacts in a closed position, such as in the
biased latching form, demonstrate somewhat lower resistance to shock.
Normally closed contacts of mechanically biased SPDT switches may also
fail at lower shock levels.
TEMPERATURE
Differential expansion or contraction of reed switches and materials used in
relay assemblies can lead to fracture of the switches. Reed relays are
capable of withstanding temperature cycling or temperature shock over a
range of at least -50C to + 100C. These limits should be applied to the
application to prevent switch failure.
CONTACT PROTECTION
Tungsten lamp, inductive and capacitive discharge load are extremely
detrimental to reed switches and reduce life considerably. Illustrated below
are typical suppression circuits which are necessary for maximum contact
life.
FIGURE 3
DC inductive loads call for either a diode or a thyristor to be placed across
the load. These circuits are necessary to protect the contacts
when inductive loads are to be switched in a circuit,
as shown in Figure 4.
FIGURE 4
Input
Input
Initial turn-on current is generally 10 times higher than the rated
operating current of the lamp. A current limiting resistor in series with
the load, or a bleeder resistor across the contacts will suppress the
inrush current. Thesesame circuits can be used with capacitive loads,
as shown in Figure 3.
R
R
Input
Input
WEBSITE: www.magnecraft.com EMAIL:info@magnecraft.com FAX ON DEMAND 1-800/891-2957, DOCUMENT 100
PAGE 69
相關(guān)PDF資料
PDF描述
W172DIP-149 RELAY REED DIL 12VDC
W389ACX-10 INDUSTRIERELAIS FLANSCH 230AC
W388CQX-7 INDUSTRIERELAIS FLANSCH 24VDC
W388ACQX-10 INDUSTRIERELAIS FLANSCH 230V
W171DIP-10 RELAY REED DIL 24VDC
相關(guān)代理商/技術(shù)參數(shù)
參數(shù)描述
W172DIP-149 功能描述:簧片繼電器 172DIP Mini Reed PCB Relay / SPDT, 0.25 A RoHS:否 制造商:MEDER electronic (Standex) 觸點(diǎn)形式:1 Form A (SPST-NO) 線圈電壓:5 VDC 最大開關(guān)功率:100 W 最大開關(guān)電流:1 A 線圈抑制二極管:No 線圈電阻:220 Ohms 端接類型:
W172DIP-150 功能描述:簧片繼電器 172DIP Mini Reed PCB Relay / SPDT, 0.25 A RoHS:否 制造商:MEDER electronic (Standex) 觸點(diǎn)形式:1 Form A (SPST-NO) 線圈電壓:5 VDC 最大開關(guān)功率:100 W 最大開關(guān)電流:1 A 線圈抑制二極管:No 線圈電阻:220 Ohms 端接類型:
W172DIP-163 制造商:Magnecraft 功能描述:
W172DIP-17 功能描述:簧片繼電器 172DIP Mini Reed PCB Relay / DPDT, 0.25 A RoHS:否 制造商:MEDER electronic (Standex) 觸點(diǎn)形式:1 Form A (SPST-NO) 線圈電壓:5 VDC 最大開關(guān)功率:100 W 最大開關(guān)電流:1 A 線圈抑制二極管:No 線圈電阻:220 Ohms 端接類型:
W172DIP-18 制造商:Magnecraft 功能描述:
發(fā)布緊急采購,3分鐘左右您將得到回復(fù)。

采購需求

(若只采購一條型號(hào),填寫一行即可)

發(fā)布成功!您可以繼續(xù)發(fā)布采購。也可以進(jìn)入我的后臺(tái),查看報(bào)價(jià)

發(fā)布成功!您可以繼續(xù)發(fā)布采購。也可以進(jìn)入我的后臺(tái),查看報(bào)價(jià)

*型號(hào) *數(shù)量 廠商 批號(hào) 封裝
添加更多采購

我的聯(lián)系方式

*
*
*