詳細(xì)介紹
瑞士Conec AG編碼器 傳感器
德國ASensTec GmbH傳感器
德國IPR - Inligente Peripherienfür Roboter GmbH工具 模塊 抓手
產(chǎn)品系列:
:王工
同號
449147851
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意大利MoxMec srl氣缸 抓手
產(chǎn)品系列:
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1. NON NECESSITA DI REGOLAZIONI NELLA BASE | 4. NON C'E' SURRISCALDAMENTO | ||||||||||||||||||||||||||||||||||||||||
Facile regolazione e taratura della base vibrante senza l'intervento di un esperto. Ideale per cambi produzioni questo grazie anche hai nuovi regolatori digitali che sono programmabili e funzionano a 110 - 220 V 50-60Hz | Gli elementi piezo sono sicuri e non c'è alcun rischio di surriscaldamento o di incendio | ||||||||||||||||||||||||||||||||||||||||
2. ALIMENTAZIONE STABILE E COSTANTE E' garantita un'alimentazione stabile e costante, senza parametri specifici e senza subire interferenze dall'esterno. Adatto per pezzi piccoli, leggeri e per microcomponenti. | 5. COMPATTO E DI DIMENSIONI CONTENUTE Le dimensioni contenute consentono l'utilizzo della base piezo dove l'applicazione dell'alimentatore convenzionale non è fattibile | ||||||||||||||||||||||||||||||||||||||||
3. NESSUN EFFETTO MAGNETICO Grazie all'assenza dei magneti nella base, nessun effetto magnetico è esercitato dall'unità di funzionamento sui pezzi da alimentare ed orientare. | 6. IMPORTANTE RISPARMIO ENERGETICO La base piezo permette una riduzione del consumo energetico pari al 70% e oltre rispetto agli alimentatori elettromagnetici | ||||||||||||||||||||||||||||||||||||||||
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BASI VIBRANTI ADER CIRCOLARI Basi vibranti piezoelettriche circolari sulle quali è possibile montare diversi tipi di contenitori di forma conica, cilindrica e a spirale con diametro da 100mm a 800 mm. | |||||||||||||||||||||||||||||||||||||||||
BASI VIBRANTI ADER LINEARI Basi vibranti piezoelettriche lineari sulle quali viene fissata una canalina sagomata per alimentare ordinatamente i pezzi. Garantiscono un'alimentazione fine e costante dei pezzi provenienti dall'autodistributore circolare, evitando inceppamenti e incastri dei particolari alimentati. | |||||||||||||||||||||||||||||||||||||||||
BASI VIBRANTI ADERAF CIRCOLARI Basi vibranti piezoelettriche circolari ad alta frequenza che, grazie alle micro oscillazioni prodotte dalle balestre piezo, permettono di alimentare microcomponenti con la massima semplicità. Hanno una tolleranza in quota centesimale quindi permettono di montare tazze lavorate a CNC, adatte per selezioni ad alta precisione. | |||||||||||||||||||||||||||||||||||||||||
BASI LINEARI CON DOPPIO MOVIMENTO La particolarità di queste basi vibranti piezoelettriche è data dal doppio movimento con un canale di andata e uno/due di ritorno. Questo permette di effettuare la selezione sul lineare tramite delle canaline lavorate a CNC garantendo un'alta precisione e la ripetibilità della selezione. Particolarmente indicate per l'alimentazione di micro componenti. In queste applicazioni, gli alimentatori circolari fungono da semplici tramogge mentre i pezzi sono perfettamente orientati nella canalina del lineare. | |||||||||||||||||||||||||||||||||||||||||
REGOLATORI DIGITALI I nuovi regolatori digitali permettono una facile taratura della base vibrante. Premendo due tasti sul controllo remoto o tramite PC/PLC è possibile cambiare frequenza e voltaggio, dati che possono essere memorizzati e richiamati in caso di cambio produzione. Sono collegabili in rete tramite bus di campo con relagolazione centralizzata di tutte le basi vibranti. Questi regolatori sono alimentati a 110÷200V 50÷60Hz o a 24V per le integrazione su impianti. |
Bracci meccanici di carico e scarico con meccanismo a camma. Progettato e ideato sulla base del “saving time” per ridurre notevolmente il tempo di progettazione e costruzione di chi realizza impianti di montaggio. Velocità, precisione, ripetibilità sono le caratteristiche dei nostri bracci meccanici. | ||||||||||||||||||||||
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AVETE UN PROBLEMA DI QUESTO TIPO? | LE RISPOSTE LE AVETE DALLE NOSTRE PINZE |
La vostra pinza si rompe frequentemente!! | Grazie al nostro meccanismo originale e brevettato, è garantita una lunga durata che nussun concorrente può realizzare. |
La forza di presa è insufficiente!! | La nostra pinza garantisce una presa decisa e delicata al tempo stesso, come le dita di una mano |
Il corpo pinza è ingombrante e difficile da applicare!! | E' disponibile una vasta gamma di pinze, la loro struttura compatta garantisce un'efficienza elevata. |
Functional principle : | |
The position compensation is made possible through specially developed elastomer elements. If a position offset occurs, the workpiece to be inserted will be moved automatically by the resulting reaction forces in such a way that jamming an wedging of the parts is prevented. Depending on the chamfer present, positioning misalignments of up to 3 mm and angular misalignments of up to 2 degrees can be compensated. The compensation takes place horizontally in the x-y plane and about the x-y-z axis for angular compensation. After extension, the element returns back into the starting postition through self-centering. |
Typ | [mm] | Empf. Handlingsgew. [kg] | LX [mm] | |
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50 | 50 | 0,6 - 1,1 | 50 | |
80 | 80 | 1,2 - 2,4 | 100 | |
100 | 100 | 2,5 - 3,5 | 150 | |
125 | 125 | 3,7 - 7,0 | 200 | |
160 | 160 | 7,1 - 18 | 300 | |
200 | 200 | 18 - 52 | 400 | |
250 | 250 | 52 - 90 | 450 | |
300 | 300 | 52 - 150 | 600 | |
The length of the gripper and part (LX Value) is the determining parameter for assembly operations with close tolerance fittings and insertion operations in which minimum insertion forces are required. The LX vlaue (see table) is the maximum value which should not be exceedes for an type. For simple insertion or placing operations, the recommended payload is to be taken as the approximate value to determine the necessary model. It can be exceeded in case of slow travelling movements. |
Model | Weight [kg] | Max. Compliance [mm] | Max. Rotation [°] | Payload [kg] | Locking Force [N bei 6 bar] | |
-50 G | 0,26 | ± 3 | ± 2 | 0,6 - 1,1 | - | |
-80 G | 0,26 | ± 3 | ± 2 | 1,2 - 2,4 | - | |
-80 Ü | 0,3 | ± 2 | ± 2 | 1,2 - 2,4 | - | |
-80 P | 0,4 | ± 2 | ± 1 | 1,2 - 2,4 | 220 | |
-80 V | 0,45 | ± 2 | ± 1 | 1,2 - 2,4 | 220 | |
-100 G | 0,42 | ± 3 | ± 2 | 2,5 - 3,5 | - | |
-100 Ü | 0,46 | ± 2 | ± 2 | 2,5 - 3,5 | - | |
-100 P | 0,7 | ± 2 | ± 1 | 2,4 - 3,5 | 360 | |
-100 V | 0,82 | ± 2 | ± 1 | 2,5 - 3,5 | 360 | |
-125 P | 1,2 | ± 2 | ± 1 | 3,7 - 7,0 | 600 | |
-160 P | 1,7 | ± 2 | ± 1 | 7,1 - 18 | 500 | |
-160 V | 1,9 | ± 2 | ± 1 | 7,1 - 18 | 500 | |
-200 P | 4,0 | ± 3 | ± 1 | 18 - 52 | 1800 | |
-200 V | 4,5 | ± 3 | ± 1 | 18 - 52 | 1800 | |
-250 P | 10,1 | ± 3 | ± 1 | 52 - 90 | 2100 | |
-250 V | 10,6 | ± 3 | ± 1 | 52 - 90 | 2100 | |
-300 P | 5,8 | ± 2,5 | ± 1 | 52 - 150 | 1800 |
Functional principle:
The compensation movement is implemented through linear roller guidance based on the compound slider principle. Compensation takes place without reaction force. The fixture can be locked in a central position using a double-action pneumatic cylinder. The compensation can take place two-dimensionally in the x-y direction. |
Information:
The maximum allowable moment is the decisive parameter for the selection of the lateral alignment devices. Additional part picking or placing forces which can work as moment loads on the guides must be taken into account. If shock loads are to be expected, in case of a collision for example, a robot load limiter should be foreseen for the protection of the guides (see pages on robot load limiter systems).
Model | KA 65 | KA 80 | KA 100 | KA 125 | KA 160 | KA 200 | KA 250 | KA 300 |
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allowable Moment [Nm] | 2 | 3 | 30 | 60 | 100 | 150 | 250 | 300 |
Payload [kg] | 0,5 | 1,0 | 2,0 | 2-5 | 10 | 15-40 | 30-80 | 50-200 |
Extension [mm] | ± 1,5 | ± 2 | ± 2 | ± 3 | ± 4 | ± 12 | ± 14 | ± 25 |
Pressure Force [N] | 150 | 200 | 400 | 800 | 1000 | 1600 | 2500 | 4000 |
Functional principle:
The compensation movement is implemented through linear roller guidance based on the compound slider principle. Compensation takes place without reaction force. The fixture can be locked in a central position using a double-action pneumatic cylinder. The compensation can take place two-dimensionally in the x-y direction. |
Information:
The maximum allowable moment is the decisive parameter for the selection of the lateral alignment devices. Additional part picking or placing forces which can work as moment loads on the guides must be taken into account. If shock loads are to be expected, in case of a collision for example, a robot load limiter should be foreseen for the protection of the guides (see pages on robot load limiter systems).
Model | KA 65 | KA 80 | KA 100 | KA 125 | KA 160 | KA 200 | KA 250 | KA 300 |
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allowable Moment [Nm] | 2 | 3 | 30 | 60 | 100 | 150 | 250 | 300 |
Payload [kg] | 0,5 | 1,0 | 2,0 | 2-5 | 10 | 15-40 | 30-80 | 50-200 |
Extension [mm] | ± 1,5 | ± 2 | ± 2 | ± 3 | ± 4 | ± 12 | ± 14 | ± 25 |
Pressure Force [N] | 150 | 200 | 400 | 800 | 1000 | 1600 | 2500 | 4000 |
Functional principle:
The position compensation takes place horizontally in the pushing or pulling direction through playless ball bearings. The insertion force is determined through pressure springs and the pressure of an integrated pneumatic cylinder. The base plate is driven out to monitor an approach or insertion motion; it is inserted to monitor a removal operation (see functional sketch). The movement of the base plate is detected through an inductive sensor. In case of quick process movements, pressure can also be applied to the cylinder to block the unit. |
Information:
The Z-axis compliance wrist can be combined with a compliance wrist in the simplest. As integrated components of an ZN, they can be used universally for tolerance compensation of lateral and angular misalignment with simultaneous fault recognition for monitoring.
Model ZN | 50 | 80 | 100 | 125 | 160 | 200 | 250 | 300 |
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Spring Force [N] | 10/20 | 20/40 | 40/180 | 200/300 | 200/400 | 400/1000 | 400/1500 | 400/2000 |
Payload [kg] | 1 | 2 | 2-3 | 5-8 | 20 | 40 | 160 | 300 |
Insertion Path [mm] | 8 | 8 | 10 | 12 | 12 | 12 | 12 | 12 |
Force Range Pneumatic [N] | - | 10-150 | 15-380 | 25-500 | 50-600 | 60-1700 | 70-1950 | 80-2200 |
Function
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Compensation
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Compensation movements
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Arias of application:
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Function:
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Compensation:
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Compensation movements:
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Areas of application:
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Functional principle | |
Robot and tool adapter plates are held in position pneumatically and form a rigid unit under normal working conditions. The release forces or moments are presrcibed through the preset air pressure. In case of an overload, the adapter plates release. |
The robot load limiter reacts to pressure forces in the z-direction, to moments about the x and y-axes and to torsional moments about the z-axis. |
Technical Data Robot Load Limiter ULS
Model | ULS 60 | ULS 80 | ULS 100 | ULS 125 | ULS 160 | ULS 200 |
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Compensation in z-axis-direction [mm] | 11,0 | 11,9 | 13,6 | 11,9 | 14,5 | 9,5 |
Compensation horizontal [grade] | 8 ° | 10 ° | 12 ° | 10 ° | 7 ° | 4 ° |
Compensation torsion [grade] | 360 ° | 360 ° | 360 ° | 360 ° | 360 ° | 360 ° |
" with Anti-rotation device [optional] | - | 90 ° | 90 ° | 40 ° | 90 ° | 90 ° |
Axial Breakaway 1 - 6 bar [N] | 113-680 | 181-1085 | 246-1477 | 453-2720 | 785-4710 | 1327-7960 |
Moment Breakaway 1 - 6 bar [Nm] | 2 - 13 | 4 - 26 | 7 - 41 | 17 - 103 | 39 - 236 | 86 - 517 |
Repeatability [mm] | ± 0,02 | ± 0,02 | ± 0,03 | ± 0,03 | ± 0,05 | ± 0,1 |
Weight [kg] | 0,36 | 0,42 | 0,75 | 1,5 | 6,7 | 9,8 |
Force- / Moment Rang |
Technical Data Robot Load Limiter with internal cable routing (ULD)
Model | ULD 60 | ULD 80 | ULD 100 | ULD 125 | ULD 160 | ULD 200 | ULD 250 | ULD 300 |
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Compensation in z-axis-direction [mm] | 11,1 | 12,1 | 12,0 | 12,1 | 15,0 | 10,4 | 15,0 | 23,0 |
Compensation horizontal [grade] | 9 ° | 11 ° | 9 ° | 11 ° | 5 ° | 4 ° | 5 ° | 5 ° |
Compensation torsion [grade] | 40 ° | 40 ° | 40 ° | 40 ° | 40 ° | 40 ° | 40 ° | 40 ° |
Axial Breakaway 1-6 bar [N] | 135-700 | 210-1100 | 300-1500 | 510-2755 | 830-4720 | 1380-6710 | 1509-9024 | 1834-11389 |
Moment Breakaway 1-6 bar [Nm] | 3-15 | 5-28 | 8-45 | 18-106 | 43-241 | 91-382 | 108-544 | 119-714 |
Repeatability [mm] | ± 0,02 | ± 0,02 | ± 0,03 | ± 0,03 | ± 0,05 | ± 0,1 | ± 0,1 | ± 0,1 |
Weight [kg] | 0,39 | 0,46 | 0,83 | 1,65 | 3,58 | 5,78 | 12,4 | 17,5 |
Force- / Moment Rang |
Two - Finger Parallel Gripper
with roller bearing
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Functional principle: | |
The parallel movement of the finger is accomplished by a jaws and pinion drive. As a result of the pressure of two opposing pistions the jaws move in a synchronised way towards each other. |
OPTIONS:
Sensors
Option C "gripper closed", Option O "gripper open". For the position of the inductive sensors please refer to the technical data of the gripper concerned.
Gripping Force Failsafe valve
A safety device for the gripping force by means of a spring is available as an option. The chuck stroke of the gripper is reduced by 50 %. The safety device can be applied for both inside and outside gripping.
Inside gripping = FS - 1
Outside gripping = FS - A
Pressure Medium
P = compressed air
H = hydraulic oil
Model | RPG 80-P | RPG 120-P | RPG 120-H | |
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Max. air pressure [bar] | 8 | 8 | 100 | |
Gripping force at 6 bar [N] | 1000 | 1000 | - | |
Gripping force at 60 bar [N] | - | - | 2000 | |
Gripping force at 100 bar [N] | - | - | 3000 | |
Weight [kg] | 8,5 | 9,0 | 10,5 | |
Stroke [mm] | 80 | 120 | 120 | |
Displacement [cm³] | 2x128 | 2x192 | 2x23,56 |
Electric Grippers
The electronic grippers in the EGS series are designed to cope with very difficult applications where a high degree of flexibility is needed.
All systems are of a strong mechanical construction which allows of a maintenance-free operation. To ensure that our system can be used to optimal effect in a wide range of different situations, we have designed 3 basic models for you to choose from.
Following basic versions are available:
EGS-EP Compact with a combined electro-pneumatic drive
- Great flexibility, because the opening width can be adjusted to any size
you wish via the electric servo drive. - Large gripping power and short travelling times via the pneumatic drive
- Extra measuring capabilities, such as the monitoring of parts dimensions
EGS-E Compact with a regulated electric servo drive
- Safe handling of sensitive parts
- Measuring and monitoring functions
- Can be used in clean rooms
EGS-ELT Light with a simple electric drive
- In areas where there is no compressed air
- Especially suited for clean rooms
Functional principle: | |
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Model EGS- | 250-EP | 250-E/-ELT | 375/1-EP | 375/1-E/-ELT | 375/2-EP |
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Gripping force electrical [N] | - | 155 | - | 180 | - |
Gripping force pneumatical at 6 bar [N] | 155 | - | 330 | - | 330 |
Duration (for 19mm strokechange in s) | 0,1 | 0,25 | 0,15 | 0,25 | 0,15 |
Stroke [mm] | 19 | 19 | 25,4 | 25,4 | 50,8 |
Repeatability [mm] | <0,1 | <0,1 | <0,1 | <0,1 | <0,1 |
Electrical performance of servo [W] | 10 | 25 | 25 | 30 | 25 |
Weight [kg] | 1,23 | 1,28 | 1,56 | 1,59 | 1,56 |
Max. air pressure [bar] | 8 | - | 8 | - | 8 |
Displacement [cm³] | 3,75 | - | 9,78 | - | 19,56 |
Cylinder bore [mm] | 16,0 | - | 22,22 | - | 22,22 |
Recommended payload [kg] | 0,5 | 0,5 | 1,5 | 0,75 | 1,5 |
Model EGS- | 375/2-E/-ELT | -500/1-EP | 500/1-E/-ELT | 500/2-EP | 500/2-E/-ELT |
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Gripping force electrical [N] | 180 | - | 330 | - | 330 |
Gripping force pneumatical at 6 bar [N] | - | 690 | - | 690 | - |
Duration (for 19mm strokechange in s) | 0,25 | 0,15 | 0,25 | 0,15 | 0,25 |
Stroke [mm] | 50,8 | 38,1 | 38,1 | 63,5 | 63,5 |
Repeatability [mm] | <0,1 | <0,1 | <0,1 | <0,1 | <0,1 |
Electrical performance of servo [W] | 30 | 40 | 75 | 40 | 75 |
Weight [kg] | 1,59 | 3,2 | 3,4 | 3,7 | 3,9 |
Max. air pressure [bar] | - | 8 | - | 8 | - |
Displacement [cm³] | - | 29,5 | - | 49,1 | - |
Cylinder bore [mm] | - | 32,0 | - | 32,0 | - |
Recommended payload [kg] | 0,75 | 4 | 2 | 4 | 2 |
Title | |||
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Name | Features | Applications | View |
PUL PUL.pdf | Miniature offset compensated basic low pressure sensors | ||
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ACL ACL.pdf | Miniature temperature compensated low pressure sensors | ||
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ACLA ACLA.pdf | Miniature amplified low pressure sensors | ||
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PXL PXL.pdf | Precision very low pressure sensors / mV-output | ||
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PXLA PXLA.pdf | Precision very low pressure sensors / Ratiometric 4V-output | ||
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Single-Chip Technologie
Title | |||
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Name | Features | Applications | View |
PCM PCM-C.pdf | Precision compensated pressure sensores / mV-output | ||
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PCM PCM-H.pdf | Precision compensated pressure sensores / mV-output | ||
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PCM PCM-P.pdf | Precision compensated pressure sensores / mV-output | ||
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PXM PXM.pdf | Precision compensated pressure sensors / mV-output | ||
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PXMA PXMA.pdf | Signal conditioned pressure sensors | ||
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PXMD PXMD.pdf | High precision digital output pressure sensors | ||
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AS 1210/1220 Datasheet coming soon | |||
Stainless Steel
Title | |||
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Name | Features | Applications | View |
ASS 82 Datasheet coming soon | |||
ASS 83 Datasheet coming soon | |||
ASS 97 Datasheet coming soon | |||
ASS 154 Datasheet coming soon | |||
ASS 5000 Datasheet coming soon | |||
Submersibles
Title | |||
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Name | Features | Applications | View |
Hydro Datasheet coming soon | |||
Food + Process
Title | |||
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Name | Features | Applications | View |
Serve 2000 Datasheet coming soon | |||
Serve 8000 Datasheet coming soon | |||
Specials
Title | |||
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Name | Features | Applications | View |
AB 1620 Datasheet coming soon | |||
Datasheet coming soon | |||
Datasheet coming soon | |||
Datasheet coming soon | |||
Datasheet coming soon | |||
Datasheet coming soon | |||
Datasheet coming soon | |||
Singleturn - Vert-X 13E
| Data sheet Vert-X_13E_5V_eng.pdf CAD file Fixation_clip_Vert-X_13E_01.zip Vert-X_13E3_axial_01.zip Vert-X_13E3_radial_01.zip | |||
Singleturn - Vert-X 22E
| Data sheet Vert-X_22E_5V_10...90_Ub_eng.pdf Vert-X_22E_5V_PWM_eng.pdf Vert-X_22E_5V_SPI_eng.pdf Vert-X_22E_24V_0.1-10V_eng.pdf Vert-X_22E_24V_0.5-4.5V_eng.pdf Vert-X_22E_24V_4-20mA_eng.pdf Vert-X_22E_24V_PWM_eng.pdf Vert-X_22E_24V_SPI_eng.pdf CAD file Fixation_clip_Vert-X_22E_01.zip Vert-X_22E1_axial_L10.85_01.zip Vert-X_22E1_axial_L16.85_01.zip Vert-X_22E1_radial_L16.85_01.zip Vert-X_22E1_radial_L21.50_01.zip Vert-X_22E2_axial_L10.85_01.zip Vert-X_22E2_axial_L16.85_01.zip Vert-X_22E2_radial_L16.85_01.zip Vert-X_22E2_radial_L21.5_01.zip | |||
Singleturn - Vert-X 27E
| Data sheet Vert-X_27E_5V_10...90_Ub_eng.pdf Vert-X_27E_5V_PWM_eng.pdf Vert-X_27E_5V_SPI_eng.pdf Vert-X_27E_24V_0.1-10V_eng.pdf Vert-X_27E_24V_0.5-4.5V_eng.pdf Vert-X_27E_24V_4-20mA_eng.pdf Vert-X_27E_24V_PWM_eng.pdf Vert-X_27E_24V_SPI_eng.pdf CAD file Fixation_clip_Vert-X_27E_01.zip Vert-X_27E1_axial_01.zip Vert-X_27E1_radial_01.zip Vert-X_27E2_axial_01.zip Vert-X_27E2_radial_01.zip | |||
Singleturn - Vert-X 31E
| Data sheet Vert-X_31E_5V_10...90_Ub_eng.pdf Vert-X_31E_5V_SPI_eng.pdf Vert-X_31E_5V_PWM_eng.pdf Vert-X_31E_24V_0.1-10V_eng.pdf Vert-X_31E_24V_0.5-4.5V_eng.pdf Vert-X_31E_24V_4-20mA_eng.pdf Vert-X_31E_24V_PWM_eng.pdf Vert-X_31E_24V_SPI_eng.pdf CAD file Vert-X_31E5a_01.zip Vert-X_31E5b_01.zip | |||
Singleturn - Vert-X 37E
| Data sheet Vert-X_37E_5V_10...90_Ub_eng.pdf Vert-X_37E_5V_PWM_eng.pdf Vert-X_37E_5V_SPI_eng.pdf Vert-X_37E_24V_0.1-10V_eng.pdf Vert-X_37E_24V_0.5-4.5V_eng.pdf Vert-X_37E_24V_4-20mA_eng.pdf Vert-X_37E_24V_PWM_eng.pdf Vert-X_37E_24V_SPI_eng.pdf CAD file Fixation_clip_Vert-X_37E_01.zip Vert-X_37E1_axial_01.zip Vert-X_37E1_radial_01.zip Vert-X_37E2_axial_01.zip Vert-X_37E2_radial_01.zip Vert-X_37E4_axial_01.zip Vert-X_37E4_radial_01.zip |