TIMERS V8.0, V9.0 Multi Functional Timer Relay
Awọn ilana Lilo ọja
- Description of Multi-functional Timer Relay:
- The multi-functional timer relay is designed to provide various timing functions based on user requirements. It can operate within a specified voltage range and offers different output types, depending on the model.
- Compare Timer Versions:
- The Version V9 of the timer relay offers more accurate frequency clock with just +/- 2sec per day fluctuation and software correction compared to Version V8, which has +/- 2% fluctuation. Additionally, V9 PCB is conformal coated for extra protection.
- Timer’s Wiring Diagram:
- Follow the appropriate wiring diagram based on the output type of the timer (Positive or Sink) to ensure proper connection and operation. Be cautious when connecting the timer to a programmer to avoid overload or damage to power sources.
- Understanding Timer Delay Relay Function:
- The timer delay relay functions provide control over output power based on specified events. Refer to the manual for detailed explanations of timing functions and terminology used in the circuit design. Understand how to initiate and trigger the timer for desired operation.
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TIMERS.SHOP
Multi-functional Timer relay. (Version V8.0 and V9.0)
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V3.5b 2025/10/19
!!! Ikilo!!!
DO NOT return the item to the original retailer. Contact the support for any problem with the item or item delivery.
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Olona-iṣẹ Aago Relay apejuwe
Module idaduro Aago iṣẹ-pupọ jẹ iyika rogbodiyan pẹlu ọpọlọpọ awọn iṣẹ idaduro aago ti a lo nigbagbogbo. O jẹ pipe fun ọpọlọpọ awọn ohun elo lati awọn iṣẹ aṣenọju si awọn iṣakoso ile-iṣẹ. Aago naa ni diẹ ẹ sii ju ọgbọn awọn iṣẹ akoko ti o yatọ lọ pẹlu agbara yiyan lati ṣe okunfa wọn nipasẹ ohun elo ti titẹ voltage si okun okunfa. Awọn olubasọrọ gbigbẹ le ṣee lo pẹlu. Aago le ṣee lo fun awọn ọgọọgọrun ti awọn ohun elo pupọ lati idaduro agbara si Circuit, fifun agbara ni aṣa gigun kẹkẹ, tabi ṣiṣẹda iyika akoko ti ara ẹni. Aago jẹ rọrun lati sopọ ati tunto. Gbogbo awọn atunto ti wa ni ipamọ patapata sinu iranti filasi inu. Aago ṣiṣẹ pẹlu 3V to 28V ipese voltage ati pe o le mu to 5amp/ 10amp ti isiyi (da lori awọn awoṣe). Eyi jẹ ki aago naa wulo fun ọpọlọpọ awọn ohun elo. O pọju lọwọlọwọ aago le faagun pẹlu lilo isọdọtun ita. Aago le ṣiṣẹ ni Ipo Agbara Kekere eyiti o dara fun awọn ohun elo ti o ni agbara batiri. Diode fo-pada ti a ṣe sinu ngbanilaaye fun asopọ taara ti awọn ẹru inductive.
Voltage ibiti:
Max current: Output type: Minimum time duration: Maximum time duration: Idle current consumption:
Iwọn iwọn otutu
3-18 V DC 5 A version 6-28 V DC 10 A version 5 A or 10 A
Rere tabi rì (Ilẹ). Da lori awoṣe
0.01 second 400 days 800 µA or 50 µA (in LOW POWER mode under certain conditions) -40 C + 80 C
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· Do not short timer’s output to the ground. It would cause excessive current, possible device overheating, and smoke.
· Do not exceed the timer’s current capacity. · Do not reverse power supply polarity. It could
cause the timer’s internal components to fail and overheat.
· Do not put a timer into a hot environment causing it to exceed specified temperate range working conditions.
· Do not disconnect the ground from the timer while under power.
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Ṣe afiwe awọn ẹya Aago
What is the difference between Version V8 and V9? V9 contains more accurate frequency clock with just +/- 2sec per day fluctuation and software correction. V8 has +/- 2% fluctuation. V9 PCB is conformal coated providing an extra layer of protection.
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Aago ká onirin aworan atọka
3.1 Connecting the timer with Positive output
*** Fun awọn ilana fifi sori ẹrọ imudojuiwọn ati awọn fidio, ṣabẹwo http://doc2.us/main View Timer’s Cookbook at http://timers.shop/Timer-Cook-Book_ep_43-1.html
3.2 Connecting the timer with Sink (Ground) output
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3.3 Connecting timer to the programmer.
Warning!!! When powering the timer from the programmer does not connect the load as the load could overload the USB supplied power. Do not connect external power to the timer as the power will be routed back to USB power source. It might destroy the USB power source as well as the programmer’s circuit.
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3.4 Connecting timer to the programmer for in-circuit programming.
Warning!!! When powering the timer from the external source, do not connect the
programmer’s power line. It might destroy the USB power source as well as the programmer’s circuit.
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1. Understanding Timer Delay Relay Function.
Agbọye gbogbo awọn iṣẹ isọdọtun idaduro akoko ti o wa ni aago multifunctional le jẹ iṣẹ-ṣiṣe ẹru. Lakoko apẹrẹ iyika pẹlu isọdọtun aago ati ọpọlọpọ awọn atunto aago, awọn ibeere bii kini o bẹrẹ awọn iṣẹ idaduro aago, ṣe akoko naa bẹrẹ pẹlu ohun elo ti agbara tabi ifihan agbara okunfa, fun bawo ni agbara iṣelọpọ yẹ ki o duro lori, ati bẹbẹ lọ, le dide ati pe o gbọdọ dahun.
Aago jẹ nìkan Circuit iṣakoso kannaa lati ṣakoso agbara iṣelọpọ ti o da lori awọn iṣẹlẹ. Ni deede, aago naa ti bẹrẹ tabi ṣe okunfa nipasẹ ọkan ninu awọn ọna meji:
· Application of power voltage · High or low trigger signal
The trigger signal can be one of the following: · A control switch (dry contacts): limit switch, push-button, the float switch · Voltage (agbara okunfa): ifihan agbara lati ẹrọ miiran, agbara ifihan agbara
Lati ṣe iranlọwọ ni oye iṣẹ ṣiṣe aago jẹ ki a wo awọn ọrọ-ọrọ ti o wọpọ ti a lo jakejado iwe afọwọkọ yii.
· Iwọn titẹ sii Voltage power voltage loo si aago. Da lori awọn ti o yan iṣẹ, awọn input voltage yoo boya pilẹṣẹ akoko iṣẹlẹ tabi agbara aago lati wa ni setan lati gba awọn okunfa ifihan agbara.
· Trigger Signal in certain timing functions, a trigger is used to initiate a timing event after the input voltage ti lo. Gẹgẹbi a ti ṣe akiyesi loke okunfa yii le jẹ iyipada iṣakoso (iyipada olubasọrọ gbigbẹ) tabi okunfa agbara (voltagati).
· Output output voltage lati aago. Awọn akoko ti o wu voltage ni iṣakoso nipasẹ iṣẹlẹ akoko ti a yan ati ọna okunfa.
Below (Figure 1) is a description of the timing functions. A timing chart shows the relationship between
Iṣagbewọle Voltage, Ifihan agbara okunfa, ati Ijade. Ṣe akiyesi pe ifihan agbara okunfa jẹ iyan fun diẹ ninu awọn iṣẹ aago ati dandan fun awọn miiran. Ṣaaju ki o to lọ nipasẹ gbogbo awọn iṣẹ ti o wa, wo ọkan akọkọ ni awọn alaye.
Olusin 1.
#
Išẹ
1
NI idaduro
Isẹ
Lori awọn ohun elo ti input voltage, akoko idaduro (t) bẹrẹ. Ni ipari idaduro akoko (t), iṣẹjade ti ni agbara. Iwọn titẹ siitage gbọdọ yọkuro lati tun isọdọtun akoko idaduro to ati mu iṣẹjade ṣiṣẹ.
Diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…….lh…….l’ }, { name: “output”, wave: ‘l.h……l.h……l’ }, {},{}, { name: “power”, wave: ‘lh…….lh…….l’ }, { name: “trigger”, wave: ‘l.H.l……H.l…..’ }, { name: “output”, wave: ‘l..h…..l..h…..l’ }]}
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Iṣẹ aago # 1 wa ni idaduro, o fun laaye lati pese agbara lẹhin igba diẹ (t). Awọn shatti akoko meji lo wa, ọkan laisi okunfa ati ọkan pẹlu okunfa kan. Aṣayan okunfa le ṣee ṣe lakoko iṣeto aago. Jẹ ki a wo chart akọkọ nibiti aago ti nfa nipasẹ titẹ sii voltage. Ni kete ti a ba ti pese agbara si aago, idaduro akoko (t) bẹrẹ, ni opin akoko idaduro (t) iṣẹjade ti ni agbara ati duro titi ti agbara si aago yoo fi yọ kuro. Yiyọ ti agbara tun awọn aago Circuit, ati aago ti šetan fun miiran ọmọ. Atẹle keji wulo nigbati a yan aṣayan okunfa kan. Ni yi pato nla, awọn okunfa on High (rere) voltage is selected. More on trigger options can be found later in the manual. Upon application of power, the timer is ready to accept the trigger signal. When the trigger is applied, the time delay (t) begins. At the end of the time delay (t) output is energized and stays on until power to the timer is removed. Another application of the trigger during time delay (t) or the output energized period, does not affect the timer function. Only the first application of the trigger matters. The diagrams can also be viewed or edited online at https://wavedrom.com/editor.html page.
2. Timer function table with charts
(Akiyesi pe nọmba iṣẹ # yoo ṣee lo lakoko iṣeto aago.)
Figure 2. # Function
1 ON DELAY
Isẹ
Nigbati titẹ sii voltage ti lo, idaduro akoko (t1) bẹrẹ. Lẹhin idaduro akoko (t1) ti pari, iṣẹjade yoo di agbara. Lati tun isọdọtun akoko idaduro to ati de-agbara iṣẹjade, titẹ sii voltage gbọdọ yọ kuro.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…….lh…….l’ }, { name: “output”, wave: ‘l.h……l.h……l’ }, {},{}, { name: “power”, wave: ‘lh…….lh…….l’ }, { name: “trigger”, wave: ‘l.H.l……H.l…..’ }, { name: “output”, wave: ‘l..h…..l..h…..l’ } ]}
2 INTERVAL ON Upon the application of input voltage, the output becomes energized, initiating
the time delay period (t1). Once the time delay (t1) concludes, the output is
then de-energized. To reset the time delay relay, the input voltage gbọdọ jẹ
ge asopọ.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…….lh…….l’ }, { name: “output”, wave: ‘lh..l…..h..l…..’ }, {},{}, { name: “power”, wave: ‘lh…….lh…….l’ }, { name: “trigger”, wave: ‘l.Hl…….Hl……’ }, { name: “output”, wave: ‘l.h..l…..h..l….’ } ]}
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# Iṣẹ
Isẹ
3
REPEAT Upon application of voltage, time delay (t3) begins, and the output is delayed
CYCLE WITH for (t4), then energized for the time delay (t1) and de-energized for (t2) until
Ibere
(t3) timeout is reached.
DÚRÒ
(t3) set to 0 will repeat the cycle indefinitely.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “output”, wave: ‘l.hlhlhlhlhlhlhlhl.’}, {},{}, { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl……………’ }, { name: “output”, wave: ‘l..hlhlhlhlhlhlhl..’ } ]}
4
REPEAT Upon application of voltage, time delay (t3) begins, and the output is energized
CYCLE WITH for (t4), then de-energized for the time delay (t1) and energized for (t2) until
Ibere
(t3) timeout is reached.
DÚRÒ
(t3) set to 0 will repeat the cycle indefinitely.
(On first)
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “output”, wave: ‘lhlhlhlhlhlhlhlhl..’}, {},{}, { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl……………’ }, { name: “output”, wave: ‘l.hlhlhlhlhlhlhlhl.’ } ]}
5 TRIGGERED Upon application of input voltage, the timer relay is ready to accept the trigger.
DÚRÒ
When the trigger is applied, the time delay (t1) begins. At the end of the time
INTERVAL 2 delay (t1), the output is energized and remains energized for the time delay
Single Cycle (t2). At the end of the time delay (t2), the output is de-energized, and the relay
is ready to accept another trigger. During both time delays (t1) and (t2), the
trigger is ignored. When activated with a secondary trigger, the time delays are
set to t3 and t4.
Notes: Older documentation refers to function 5 as cycling. See functions 3, 4,
8, and 9 for cycling functionality.
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# Iṣẹ
Isẹ
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ },
{ name: “trigger”, wave: ‘l.Hl..HlHl…..Hl..’ },
{ name: “trigger”, wave: ‘l………Hl..Hl…’ }, { name: “output”, wave: ‘l..h.l.hl..h.l…..’ } ]}
6
REPEAT Upon application of voltage, time delay (t3) begins, and the output is delayed
CYCLE WITH for t4. Then t1 and t2 cycle start. The output is de-energized for the time delay
Ibere
(t1) and energized for (t2) until (t3) timeout is reached.
DÚRÒ
When trigger 1 is activated, the cycle advances to the start of the t1 duration.
And when trigger 2 is activated, the cycle advances to the start of t2 duration.
(t3) set to 0 will repeat the cycle indefinitely.
Display diagram online: https://wavedrom.com/editor.html #Function 06 { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l……Hl……….’ }, { name: “trigger”, wave: ‘l………..Hl…..’ }, { name: “output”, wave: ‘l…h.lh.l.hl.h.l..’ } ]}
7 DELAYED Upon the application of input voltage, the initial time delay (t1) starts. After INTERVAL the completion of this initial time delay (t1), the output becomes energized and Single Cycle stays energized for the duration of the second time delay (t2). Following the conclusion of this second time delay (t2), the output is de-energized. To reset the time delay relay, the input voltage gbọdọ yọ kuro.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…….lh…….l’ },
{ name: “output”, wave: ‘l..h.l……h.l….’ },
{},{}, { name: “power”, wave: ‘lh…….lh…….l’ }, { name: “trigger”, wave: ‘l.Hl…….Hl……’ }, { name: “output”, wave: ‘l…h.l……h.l…’ } ]}
8
REPEAT Upon application of voltage, time delay (t3) begins, and the output is energized
YICYCLE
for the time delay (t1). At the end of the time delay (t1), the output is de-
(Ni akọkọ)
energized for the time delay (t2) and continues to cycle until (t3) is reached.
t3 ṣeto si 0 yoo tun awọn ọmọ titilai.
t4 is used to insert an inactive phase. t4 set to 0 will force the cycle to end
when t3 expires.
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# Iṣẹ
Isẹ
Display diagram online: https://wavedrom.com/editor.html
{ signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “output”, wave: ‘lhlhlhlhlhlhlhlhl..’}, {},{}, { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl……………’ }, { name: “output”, wave: ‘l.hlhlhlhlhlhlhlhl.’ }
]}
9
REPEAT Upon application of voltage, time delay (t3) begins, and the output is de-
YICYCLE
energized for the time delay (t1). At the end of the time delay (t1), the output is
(Off First) energized for the time delay (t2) and continues to cycle until (t3) is reached.
t3 ṣeto si 0 yoo tun awọn ọmọ titilai.
t4 is used to insert an inactive phase. t4 set to 0 will force the cycle to end
when t3 expires.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “output”, wave: ‘l.hlhlhlhlhlhlhlhl.’}, {},{}, { name: “power”, wave: ‘lh…………….l’ },
{ name: “trigger”, wave: ‘l.Hl……………’ },
{ name: “output”, wave: ‘l..hlhlhlhlhlhlhl..’ } ]}
10
TAN/PA
Lori ohun elo ti input voltage, the timer relay is ready to accept a trigger.
DÚRÒ
When the trigger is applied, the time delay (t1) begins. At the end of the time
delay (t1), the output is energized. When the trigger is removed, the output
remains energized for the time delay (t2). At the end of the time delay (t2), the
output is de-energized, and the time delay relay is ready to accept another
trigger. If the trigger is removed during the time delay period (t1), the output
will remain de-energized, and the time delay (t1) will reset. If the trigger is re-
applied during the time delay period (t2), the output will remain energized, and
the time delay (t2) will reset.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H……l………’ }, { name: “output”, wave: ‘l….h……..l….’ } ]}
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# Iṣẹ
Isẹ
11 TRIGGERED Upon application of input voltage, the timer relay is ready to accept a trigger.
ON DELAY When the trigger is applied, the time delay (t) begins. At the end of the time
delay (t), the output is energized and remains in that condition as long as either
the trigger is applied, or the input voltage remains. If the trigger is removed
during the time delay (t), the output remains de-energized, and the time delay
(t) tun.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H……l…H.l…’ }, { name: “output”, wave: ‘l….h…l………’ } ]}
12 OFF DELAY Upon application of input voltage, the timer relay is ready to accept a trigger. When the trigger is applied, the output is energized. Upon removal of the trigger, the time delay (t) begins. At the end of the time delay (t), the output is de-energized. Any application of the trigger during the time delay will reset the time delay (t) and the output remains energized.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l…Hl.Hl…’ },
{ name: “output”, wave: ‘l.h……l.h…..l.’ }
]}
13 SINGLE-SHOT Upon application of input voltage, the timer relay is ready to accept a trigger.
WITH TIME When the trigger is applied, the output is energized, and timer delay (t) begins.
Tunto
Any application of the trigger during the time delay will reset the time delay (t)
and the output remains energized.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l.Hl.Hl…..’ }, { name: “output”, wave: ‘l.h…l..h……l..’ } ]}
14 SINGLE-SHOT Upon application of input voltage, akoko yii ti šetan lati gba okunfa kan. Nigbati a ba lo okunfa naa, iṣẹjade naa ni agbara, ati idaduro akoko (t) bẹrẹ. Lakoko idaduro akoko (t), a ko bikita okunfa naa. Ni opin akoko idaduro (t), o wu ti wa ni de-agbara, ati awọn akoko idaduro ti šetan lati gba miiran okunfa.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l.HlHl……’ }, { name: “output”, wave: ‘l.h…l..h…l…..’ } ]}
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# Iṣẹ
Isẹ
15 TRIGGERED Upon application of input voltage, the timer relay is ready to accept the trigger.
DÚRÒ
When the trigger is applied, the time delay (t1) begins. At the end of the time
INTERVAL delay (t1), the output is energized and remains in that condition for the time
Single Cycle delay (t2). At the end of the time delay (t2), the output is de-energized, and the
relay is ready to accept another trigger. During both time delay (t1) and time
idaduro (t2), okunfa ti wa ni bikita.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl..H……l..’ }, { name: “output”, wave: ‘l…h..l…h..l….’ } ]}
16 INTERVAL ON Upon application of input voltage, the timer relay is ready to accept the trigger. WITH OFF When the trigger is applied, the output is energized, and the time delay (t) TRIGGER begins. At the end of the time delay (t), the output is de-energized. Application of trigger during time delay (t) will cause time delay (t) to expire and output is de-energized.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl.H….l…..’ }, { name: “output”, wave: ‘l.h..l..h…l……’ } ]}
17 INTERVAL ON Upon application of input voltage, the timer relay is ready to accept the trigger. TRIGGER When the trigger is applied, the output is energized, and the time delay (t)
CONTROLLED begins. At the end of the time delay (t), the output is de-energized. Removal of the trigger during time delay (t) will cause time delay (t) to expire and output is de-energized.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H..l.H…..l…..’ }, { name: “output”, wave: ‘l.h..l.h….l……’ } ]}
18 FREE FORM Upon application of voltage, time delay begins, and free-form pattern
ONE TIME programmed by the user is executed. When the pattern is completed it can be
(Up to 48
retriggered again.
iṣeto ni
ojuami)
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# Iṣẹ
Isẹ
19 FREE FORM Upon application of voltage, time delay begins, and free pattern cycle
REPEATED programmed by the user is executed. Once started the cycle will be repeated
(Up to 48
over and over.
iṣeto ni
ojuami)
20 CANCELED Upon application of input voltage, the output is energized, and the time delay INTERVAL (t) begins. At the end of the time delay (t), the output is de-energized. If the trigger is applied during the time delay (t) the output is de-energized and the delay canceled. Input voltage gbọdọ yọkuro lati tun atunṣe akoko idaduro pada.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh……lh……..l’ }, { name: “trigger”, wave: ‘l…………Hl….’ }, { name: “output”, wave: ‘lh…..l.h…l…..’ } ]}
21 SINGLE SHOT Upon application of input voltage, the timer is ready to accept a trigger. When TIME RESET the trigger is applied, the output is energized, and timer delay (t) begins. Any HOLD ON application of the trigger during the time delay will reset the time delay (t) and TRIGGER the output remains energized. If the trigger still applied after the delay (t) the output remains energized until the trigger is removed.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl..HlHl..H….l.’ }, { name: “output”, wave: ‘l.h..lh….lh….l.’ } ]}
22 FOLLOW Upon application of input voltage, a standard relay is ready to accept a trigger. When the trigger is applied, the output is energized. The output continues to be energized until the trigger is removed, at which point the output is deenergized.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl..HlHl..H….l.’ }, { name: “output”, wave: ‘l.hl..hlhl..h….l.’ } ]}
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# Iṣẹ
Isẹ
23 WATCHDOG When an input voltage is applied, the timer relay’s output becomes energized,
1
and the relay is primed to receive a trigger signal. If the trigger is activated at
any point during the first-time delay period (t1), this action will reset the timer
for t1, and the output continues to remain energized. Once the time delay
period t1 concludes without further triggers, the output is then de-energized for
a second time delay period (t2) and then the cycle repeats.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.HlHl….HlHlHlHl.’ }, { name: “output”, wave: ‘lh……lh……..l’ } ]}
24 FUNCTION 24 When an input voltage ti lo, aago ti šetan lati gba titẹ sii okunfa. Ti iye akoko laarin awọn okunfa ba kere ju t1 ati awọn iṣiro aago n awọn okunfa itẹlera lẹhinna iṣẹjade tẹle okunfa titi iye akoko laarin awọn okunfa ti kọja t1.
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trg blue”, wave: ‘l.HlHlHlHl..HlHlHl.’ }, { name: “trg green”, wave: ‘l………..HlHlHl.’ }, { name: “output”, wave: ‘l…..hlhl………’ } ]} Practical use. This function can be used as a turn signal alarm configured to be activated after set number of cycles. The timer output will be activated for t2 or the duration of the trigger. The blue and green triggers are connected to turn signal bulbs on each side. The trigger is configured to mode 2 and the trigger function set to XOR. Function XOR will allow either blue or green trigger to activate the alarm, but the simultaneous execution during hazard activation would cancel the trigger.
25 OUTPUT ON Upon application of input voltage, the timer relay is ready to accept trigger
TRIGGER input. When the trigger is applied the output is energized for the time delay
CHANGE (t1). The release of the trigger also energizes the output for time (t2). The
optional delay (t3) and (t4) can be inserted before the output is energized.
Display diagram online: https://wavedrom.com/editor.html
ifihan agbara: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H…l..H…..l…’ }, { name: “output”, wave: ‘l.hl..h.lhl….h.l.’ } ]}
26 BUTTON Upon application of input voltage, the timer relay is ready to accept trigger
INTERFACE input. With short (< t2) application of trigger the output is energized for the
PẸLU
time delay (t1). The second application of the trigger will de-energize the
TIMEOUT output. With long (>t2) application of trigger, the output is energized and held
energized until the trigger is removed.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H.l.Hl…..Hl.Hl.’ }, { name: “output”, wave: ‘l.h.l.h….l.h..l..’ } ]}
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28 FUNCTION 28 Upon application of input voltage, the timer relay is ready to accept trigger
input. With short (< t2) application of trigger the output is energized for the
time delay (t1). The second application of the trigger will reset delay (t1). With
long (>t2) application of trigger, the output is energized and held energized
until the trigger is removed. With long (>t2) application of trigger during the
active output, the timeout is canceled and output stays energized until the
trigger is removed.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H.l.HlHl…HlH.l.’ }, { name: “output”, wave: ‘l.h.l.h….l.h…l.’ } ]}
29 INTERVAL Upon application of input voltage, the timer relay is ready to accept the trigger.
PẸLU
When the trigger is applied the output is energized and the time delay (t1)
LOCKOUT begins. At the end of the time delay (t1), the output is de-energized and
Single Cycle remains in that condition for the time delay (t2). During both time delay (t1)
ati idaduro akoko (t2), a ko bikita okunfa naa.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl..H……l..’ },
{ name: “output”, wave: ‘l.h.l….h.l…….’ }
]}
30
AGBARA
Timer operation is intended as a countdown timer. The countdown stops when
INDEPENDENT power is removed but continues when power is reapplied. To run the timer in
Aago
this mode first configure timer time, function and trigger. Activating trigger for
> 5 secs resets the timer and countdown starts. When the sum of the time is
greater than the preset time the output becomes active. Activating trigger for >
5 secs resets the countdown.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…lh…..lh….l’ }, { name: “output”, wave: ‘l…………..h..l’ } ]}
31 REPEAT The function is similar to Function #5 (Repeat cycle). The duration of the first
RANDOM active phase of the cycle is randomly calculated with the range set between t1
YICYCLE
and t2. The passive phase is between t3 and t4.
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Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ },
{ name: “trigger”, wave: ‘lHl…………….’ },
{ name: “output”, wave: ‘lh.l.h..l.h….l…’ }, {}, {}, { name: “power”, wave: ‘lh…………….l’ }, { name: “output”, wave: ‘lh.l.h..l.h….l…’ } ]}
32 FOLLOW Upon application of input voltage, awọn ti o wu wa ni agbara, ati awọn akoko idaduro
WITH INITIAL (t) begins. At the end of the time delay (t), the output follows the trigger level.
ON
When the trigger is applied, the output is energized and continues to be
energized until the trigger is removed. When the trigger is removed the output
ti wa ni de-agbara.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l…..HlHl..H….l.’ }, { name: “output”, wave: ‘lh.l..hlhl..h….l.’ } ]}
33 COUNTER Upon application of input voltage, aago ti šetan lati gba okunfa naa. Ni kete ti a ba rii okunfa nọmba tito tẹlẹ ti awọn iyipo (n) iṣẹjade ti mu ṣiṣẹ fun iye akoko (t1). Awọn okunfa ti wa ni bikita nigba ti nṣiṣe lọwọ o wu. Ni opin akoko idaduro (t1), aago ti šetan lati gba okunfa naa.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘lP…………….l’ }, { name: “output”, wave: ‘l…h.l..h.l..h.l..’ } ]}
34 DELAY ON Upon application of input voltage, the timer relay is ready to accept a trigger.
PẸLU
When the trigger is applied, the time delay (t1) begins. At the end of the time
TIMEOUT delay (t1), the output is energized. The output remains energized for a period
of t2 unless the trigger is removed. If trigger is removed the output de-
energized and cycle ends.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l..H……l.’ }, { name: “output”, wave: ‘l…h..l….h…l..’ } ]}
35 OFF DELAY Upon application of input voltage, the output is energized for t2. The timer
PẸLU
relay is ready to accept a trigger. When the trigger is applied, the output is
INITIALIZATI energized. Upon removal of the trigger, the time delay (t) begins. At the end of
ON
the time delay (t), the output is de-energized. Any application of the trigger
during the time delay will reset the time delay (t) and the output remains
agbara.
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Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ },
{ name: “trigger”, wave: ‘l….Hl…HlHl…..’ },
{ name: “output”, wave: ‘lh.l.h..l.h….l…’ } ]}
36 FOLLOW Upon application of input voltage, the timer relay is ready to accept a trigger.
PẸLU
When the trigger is applied, the output is energized and continues to be
LOCKOUT energized until the trigger is removed. When the trigger is removed the output
is de-energized and period t1 starts. During the t1 period the timer will not
respond to the trigger.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.HlHl.H…l….’ }, { name: “output”, wave: ‘l.hl…hl..h..l….’ } ]}
37 FLIP FLOP Upon application of input voltage, the timer relay is ready to accept a trigger.
PẸLU
Once the trigger is detected preset number of cycles (n) the output is flipped.
AKIYESI
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘lP…………….l’ }, { name: “output”, wave: ‘lhlhlhlhlhlhlhlhlhl’ } ]}
38 FOLLOW Upon application of input voltage, the timer relay is ready to accept a trigger.
PẸLU
When the trigger is applied, the output is energized and continues to be
LOCKOUT 2 energized until the trigger is removed. When the trigger is removed the output
is de-energized and period t1 starts. During the t1 period the timer will not
respond to the trigger and the lockout time t1 will reset.
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl.Hl..Hl..Hl.’ }, { name: “output”, wave: ‘l.hl……..hl..hl.’ } ]}
39 SINGLE-SHOT Upon application of input voltage, the timer relay is ready to accept a trigger. WITH TWO When the trigger is applied, the output is energized, and the time delay (t1) TRIGGERS begins. During the time delay (t1), the trigger is ignored. At the end of the time delay (t1), the output is de-energized, and the time delay is ready to accept another trigger. The same applies to trigger 2 (Green)
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l.HlHl……’ }, { name: “trigger”, wave: ‘l………….Hl…’ }, { name: “output”, wave: ‘l.h…l..h…lh.l..’ } ]}
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40 SINGLE-SHOT Upon application of input voltage, the timer relay is ready to accept a trigger.
WITH TWO When the trigger is applied, the output is energized, and the time delay (t1)
TRIGGERS 2 begins. During the time delay (t1), the trigger is ignored. At the end of the time
delay (t1), the output is de-energized, and the time delay is ready to accept
another trigger. Application of the trigger 2 would reset the time delay to t2.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H….l.Hl……..’ }, { name: “trigger”, wave: ‘l………..Hl…..’ }, { name: “output”, wave: ‘l.h…l..h……l..’ } ]}
41 ACCUMULAT Upon application of input voltage, the timer relay is ready to accept a trigger.
OR
When the trigger is applied, the output is energized, and timer delay (t) begins.
Any application of the trigger during the time delay will reset the time delay (t)
and the output remains energized. Each consecutive trigger application
increases the timer delay (t1).
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.HlHl.HlHlHl…’ }, { name: “output”, wave: ‘l.h.lH…lH…..l..’ } ]}
42 SINGLE SHOT Upon application of input voltage, the timer relay is ready to accept a trigger. WITH CANCEL When the trigger is applied, the output is energized, and timer delay (t) begins. Any application of the trigger during the time delay will reset the time delay (t) and the output remains energized. Each consecutive trigger application sets the next time delay until reached the timer delay (t4). The next application of trigger will cancel the output. The output is also cancelled if time delay is set to 0.
Display diagram online: https://wavedrom.com/editor.html
{ signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.HlHl….Hl.Hl.’ }, { name: “output”, wave: ‘l.h.lh….l..h.l…’ }
]}
43 WATCHDOG When an input voltage is applied, the timer relay’s output becomes energized,
2
and the relay is primed to receive a trigger signal. If the trigger is activated at
any point during the first-time delay period (t1) the time delay period (t1) is
reset, and stays reset while trigger is active. The output stays energized. When
trigger goes inactive the time delay (t1) starts. Once the time delay period t1
concludes without further triggers, the output is then de-energized for a second
time delay period (t2). Trigger application is ignored during delay period (t2).
Upon completion of delay period (t2) the output is energized, and delay period
(t1) is reset.
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44 TRIGGERED DELAY
INTERVAL Multiple Cycles
Isẹ
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.HlHl.Hl.HlHlHlHl.’ }, { name: “output”, wave: ‘lh….l..h……..l’ } ]}
Lori ohun elo ti input voltage, akoko yii ti šetan lati gba okunfa naa. Nigbati a ba lo okunfa naa, idaduro akoko (t1) bẹrẹ. Ni ipari akoko idaduro (t1), iṣelọpọ ti wa ni agbara ati pe o wa ni ipo yẹn fun idaduro akoko (t2). Ni opin akoko idaduro (t2), o wu ti wa ni de-agbara, ati awọn yii ti šetan lati gba miiran okunfa. Lakoko idaduro akoko mejeeji (t1) ati idaduro akoko (t2), a ṣe akiyesi okunfa naa.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl..H……l..’ }, { name: “output”, wave: ‘l…h..l…h..l….’ } ]}
45 INTERVAL Upon application of input voltage, the timer relay is ready to accept the trigger.
PẸLU
When the trigger is applied the output is energized and the time delay (t1)
LOCKOUT begins. At the end of the time delay (t1), the output is de-energized and
Multiple Cycles remains in that condition for the time delay (t2). During both time delay (t1)
ati idaduro akoko (t2), a ko bikita okunfa naa.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.Hl.Hl..H……l..’ }, { name: “output”, wave: ‘l.h.l….h.l..h.l..’ } ]}
46
TAN/PA
Lori ohun elo ti input voltage, the timer relay is ready to accept a trigger.
DELAY WITH When the trigger is applied, the time delay (t1) begins. At the end of the time
CANCEL delay (t1), the output is energized. The output remains energized for the time
delay (t3). If trigger is applied while output is active the time delay (t2) begins.
At the end of the time delay (t2), the output is de-energized. After output is de-
energized the time delay (t4) begins during which the trigger application is
bikita.
Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.H…l…H…l….’ }, { name: “output”, wave: ‘l….h…….l…..’ } ]}
47
TAN/PA
Lori ohun elo ti input voltage, the timer relay is ready to accept a trigger.
DELAY WITH When the trigger is applied the output is activated and the time delay (t1)
CANCEL AND begins. At the end of the time delay (t1), the output continues to be energized
FOLLOW even if trigger is removed. The output remains energized for the time delay
(t3). If trigger is applied while output is active the time delay (t2) begins. At
the end of the time delay (t2), the output is de-energized. After output is de-
energized the time delay (t4) begins during which the trigger application is
bikita.
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Display diagram online: https://wavedrom.com/editor.html { signal: [ { name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘l.HlH.l…H…lHl..’ }, { name: “output”, wave: ‘l.hlh……..l.hl..’ } ]}
48 COUNTER Upon application of input voltage, the timer is ready to accept the trigger. WITH TIME Once the trigger is detected preset number of cycles (n) applied during period
RESTRICTION shorter than t1 the output is activated for the duration (t2). The trigger is ignored during the active output. At the end of the time delay (21), the timer is ready to accept the trigger.
Display diagram online: https://wavedrom.com/editor.html { signal: [
{ name: “power”, wave: ‘lh…………….l’ }, { name: “trigger”, wave: ‘lpppl..pplpl.pppl..’ }, { name: “output”, wave: ‘l..h.l………h.l.’ } ]}
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3. Timer trigger.
As described above timer is initiated or triggered by one of two methods: · Application of power voltage · High or low trigger signal
The trigger signal can be one of the following: · A control switch (dry contacts): limit switch, push-button, or float switch · Voltage (agbara okunfa): ifihan agbara lati ẹrọ miiran, agbara ifihan agbara
3.1 Timer trigger operation with charts.
Olusin 3.
Okunfa giga
Upon application of power the time delay relay is ready to accept the trigger. The transition of the voltage on the trigger wire from low to high will trigger the start of the time delay (t).
Low okunfa
Upon application of power, the time delay relay is ready to accept the trigger. The transition of the voltage on the trigger wire from high to low will trigger the start of the time delay (t).
To use trigger input with dry contact (like switch or button), trigger wire would need to be `pulled’ to either High or Low voltage. Iṣeto aago ngbanilaaye fun okun waya okunfa lati ṣeto si boya fa si giga, nibiti a ti lo lọwọlọwọ kekere kan lati tọju okun waya ni High voltage tabi ilẹ fifi okun okunfa ni Low voltage. Tabili ti o tẹle n ṣe afihan nigbati o le tunto okun waya okunfa si Giga tabi si Low.
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3.2 Eksample ti okunfa setup.
Olusin 4.
Trigger pull
Apejuwe
iṣeto ni
Trigger pulled to
Kekere
The trigger is set to be pulled to Low. Upon button or switch engagement the trigger voltage jumps to High (positive voltagati).
The trigger could also be a positive voltage from the external source applied to the trigger wire.
Note: event could be triggered either by applying or removing power.
The shown Pull-down resistor is built into the timer and does not need to be connected externally.
Wiring diagram and trigger chart
Trigger pulled to
Ga
The trigger is set to be pulled to High. Upon button or switch engagement the trigger voltage jumps to Low (grounded).
The trigger could also be the Ground applied to the trigger wire.
Note: event could be triggered either by applying or removing ground.
The shown Pull-up resistor is built into the timer and does not need to be connected externally.
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3.3 Timer trigger configuration table.
(Akiyesi pe nọmba iṣẹ okunfa aago # yoo ṣee lo lakoko iṣeto aago.)
Olusin 5.
Iṣeto okunfa
*** ***
1 2 6 10 14 3 7 11 15 4 8 12 16 5 9
Trigger pull
Low Low High High
Nfa ti nṣiṣe lọwọ
Wo awọn akọsilẹ ni isalẹ
Apejuwe
Ga Low Low High
Trigger is disabled For dry contacts between trigger wire and positive. For a case where the voltage is applied to a trigger. For dry contacts between trigger wire and ground. For a case where the ground is applied to the trigger.
* Trigger functions ensure the trigger transition from inactive to activate state upon startup. Applies to functions: all **Trigger acts as an enable/disable switch. Applies to function: 5, 6, 8, 9, 18, 19, 31 ***Trigger utilizing flip-flop operation. Applies to functions: all
Example ti awọn eto okunfa ni 2, 10, ati 14 ni lilo Išė 5. Nigbati a ba ṣeto okunfa si 2, o bẹrẹ iyipo naa. Ṣiṣeto Nfa si 10 yi iṣẹ naa tan ati pipa. Ṣiṣeto rẹ si 14 ṣiṣẹ bi okunfa isipade-flop, eyiti o tan iṣẹ naa pẹlu okunfa akọkọ ati pipa pẹlu keji. Ilana isipade-flop yii wulo fun gbogbo awọn iṣẹ.
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3.4 Multi-trigger operation.
Awọn ẹya ara ẹrọ Circuit awọn igbewọle okunfa meji: Blue ati Green. Lati lo awọn okunfa mejeeji ni akoko kanna ṣeto awọn okunfa si awọn atunto ti o yẹ ki o yan iṣẹ okunfa lati ọkan ninu atẹle naa:
Trigger Function Name Description
Buluu nikan
Blue acts as a function trigger. Green is enabled for two
trigger functions such as Function 38.
Alawọ ewe nikan
Alawọ ewe n ṣiṣẹ bi okunfa iṣẹ, Blue ko bikita
ATI
Logical AND operation. For a timer to be triggered
both triggers must be Active.
OR
Logical OR operation. For a timer to be triggered, only
one of the triggers needs to be Active.
XOR
Logical XOR operation. For a timer to be triggered
only one of the triggers has to be in Active, not both.
Blue main / Green
Blue acts as a function trigger, Green cancels the
fagilee
function execution by resetting the timer.
Blue main / Green
Blue acts as a function trigger, Green cancels the
cancel V2
function execution only if Blue trigger is inactive by
resetting the timer.
AND then OR
Logical AND operation. For a timer to be triggered
both triggers must be Active. Then active trigger
maintained with Logical OR where only one if the
triggers need to be active.
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Aworan atọka ti o tẹle n ṣapejuwe okunfa ipari akojọpọ akojọpọ ti ipilẹṣẹ fun iṣẹ okunfa kọọkan ti o yan. Aago naa ṣe iṣiro iye okunfa ipari yii nipa sisọpọ awọn okunfa Blue ati Green, ati lẹhinna lo iye iṣiro yii si iṣẹ oniwun.
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Iṣiṣẹ ti 'Blue Main/Green Fagilee' okunfa n ṣiṣẹ ni ọna alailẹgbẹ. Lati ṣapejuwe, ronu Iṣe #01 gẹgẹbi aṣoju tẹlẹample. Ṣiṣe okunfa buluu naa bẹrẹ iṣẹ ti iṣẹ naa, lakoko ti o n ṣiṣẹ okunfa alawọ ewe ṣiṣẹ lati tun iṣẹ ṣiṣe ti nlọ lọwọ.
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Ipele ti nfa
Ipele-ilẹ naa pinnu iye akoko eyiti okunfa gbọdọ wa ni ṣiṣiṣẹ tabi aiṣiṣẹ ṣaaju ki aago to jẹwọ.
Ikọju iṣaju akọkọ
Iye akoko lẹsẹkẹsẹ ti o tẹle agbara ibẹrẹ lakoko eyiti aago ko wa ni idahun si ifihan agbara okunfa.
Nfa voltage
Awọn okunfa voltage can reach the supply voltage. The table below shows the levels at which the trigger threshold is reached.
Trigger config
Active when high Active when low
Threshold (Approx.)
1.2 V 1.0 V
Edge Direction
Low -> High High -> Low
Event generated when
Input crosses 1.2 V Input drops below 1.0 V
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Ipo Ijade Aago
Aago o wu mode faye gba olumulo lati ṣeto boya ese o wu, ibi ti awọn o wu wa lori ati ki o lọ si pa lesekese, tabi mimu ilosoke / dinku, ibi ti o wu jẹ PWM (Pulse Width Modulation) dari ati r.amps up to 100% duty in about 4 seconds. The gradual output is excellent for the lighting system to increase and dim the lights gradually.
5. Timer Output type
In some circumstances, it is required to supply reversed output to the load, so instead of supplying power to the load during the time delay (t), the output is de-energized. The following diagram shows a sample aago isẹ pẹlu deede ati ifasilẹ awọn o wu.
Aago ti wa ni atunto pẹlu iṣẹjade deede.
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siseto Aago
Circuit pirogirama ni a nilo lati yi awọn atunto aago naa pada.
Olupilẹṣẹ ti lo fun:
· Reading timer’s configuration. · Changing timer’s configuration. · Uploading selected function into the timer’s memory. · Controlling timer’s output. · Reading timer’s trigger lines.
Awọn siseto aago le ṣee ṣe boya nipa sisopọ aago taara si olutọpa 2.3 tabi sisopọ pirogirama si aago fun siseto inu-yika Nọmba 2.4.
Eto ti aago ni yiyan iṣẹ ti o yẹ, okunfa ati awọn aye akoko. Tẹle awọn igbesẹ ti o wa ni isalẹ lati ṣaja iṣẹ naa 12 (akoko idaduro akoko), nfa 2 (nfa lori nyara voltage) ati idaduro ti awọn aaya 10:
· Connect the timer to the programmer. · Power the programmer by plugging into a computer or USB power bank. · Move the programmer’s switch to ON position to supply the power to the timer. If the
switch was in ON position when programmer was powered on then turn the switch to OFF position wait for a couple of seconds and then turn it back on. · After a couple of seconds, the programmer blue LED would light up confirming the programmer is communicating with the timer. · Wa fun timers.shop Wi-Fi network on the laptop or phone and connect to it. · Open the browser on the phone/computer and enter address 192.168.4.1 into the address bar of the browser. · Go to the Timer’s Config menu and make necessary changes.
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Laasigbotitusita
Awọn aami aisan
Awọn igbesẹ ipinnu
The timer is not connecting to · Verify three wires (Black, Red, and White) are
the programmer, and the
properly connected between the programmer and the
programmer’s blue LED is not
timer and not shorted. Shorting White and Red might
LATI.
render the programmer inoperable.
· Verify continuity of each wire.
· Turn the programmer’s power switch to the OFF
ipo.
· Push the programmer’s two buttons located near the
USB socket. The buttons could be pushed in any
sequence. This will restart the programmer.
· Supply power to the timer by moving the switch to the
ON position. It might take a couple of seconds for the
programmer to communicate to the timer.
· Contact the support if you are still having issues with
the programmer’s connection.
The Select Function menu does not display any available functions, and the Timers Configuration menu is empty, including its functions and timing settings. The configuration seems to have been deleted from the timer. The programmer successfully communicates with the timer, but when going to select the function, the drop-down is empty.
· The programmer is not successfully connected to the timer and cannot pull the existing timer information to be displayed. For the programmer to display available functions and settings, the timer must successfully communicate with the programmer, and the blue LED should be ON.
· The programmer might not have the up-to-date functions list for V9 timers. Make sure the programmer has been updated to the latest version. More information can be found here: https://timers.shop/Universal-Programmerfirmware_ep_61-1.html
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Shorting the programmer’s red and white wires may damage the programmer’s data line. To test the programmer’s data line, connect to the programmer’s WI-FI, open the following address in the browser: http://192.168.4.1/testdataline, and follow the instructions.
8. Low Power Ipo
The timer can be configured in Low Power mode, which drops the idle current consumption to a much lower value. This mode makes the timer suitable for battery operation. For example, if we take a 9V battery with 500mAh capacity, we can calculate the duration the timer can run in idle mode. 500mah/0.020ma = 25000 hours. The timer’s Low Power mode is enabled by default. But several conditions must be met to have the lowest power draw: 1. The trigger should be configured to #2 (if used), without Pull up. The trigger voltage should be at 0v
for low power consumption. 2. The output is at 0V. 3. The following Functions are enabled for Low Power mode: 2, 10, 12 – 17, 20 29.
Note: Due to the internal power storage the timer will not reset with a brief power interruption. To reset the timer configured with Low Power mode, the power outage yẹ ki o jẹ diẹ sii ju iṣẹju 3 lọ.
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Awọn ẹya ẹrọ
9.1 Timer programming circuit (sold separately)
10. YouTube Videos
https://timers.shop/Timer-V8-Videos_ep_57-1.html
11. Wulo ìjápọ
Latest firmware and function updates: https://timers.shop/Universal-Programmer-firmware_ep_61-1.html
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TIMERS V8.0, V9.0 Multi Functional Timer Relay [pdf] Afowoyi olumulo V8.0, V9.0, V8.0 V9.0 Multi Functional Timer Relay, V8.0 V9.0, Multi Functional Timer Relay, Timer Relay |