The LRR85_USB can be configured to will allow attached sensors to trigger relays at a predetermined setting. 0 to 5 volt sensors can
be connected to the board which will convert the voltage to a numerical value between 0 and 255. You can set what value you want the
relays to trigger! Trigger above, below or in between values. Set delays after the value has been reached (light stays on for
10 minutes after sensor activation). Options are limitless!
The TLR85_USB Reactor Relay uses a USB cable to connect to your computer to configure the board. Remember, once the board is configured,
the computer is no longer needed. Making this the ideal choice for controlling relays using a sensor or contact closure!
8 5-Amp Relay Installed
- Single Pole Double Throw (SPDT) Relay
- Temperature Rating -40° C to 85° C
Onboard USB Interface Module
- Configure Board with USB Connection
- Plugs Directly into USB Port
- Use to Configure Relay
- 256 Different Trigger Points
- 8 Background Timers Available
- 4 Rotation Counters Available
- Configure Activation Sequences
The LRR85_USB Reactor Controller must be configured using a computer and the included Base Station Software. Once configured, a Reactor will operate without a computer. By choosing a USB version you will connect your computer to your controller via a USB cable. This is the easiest and most popular way to connect to the Reactor Board. At any time, a computer may monitor the Reactor, Trigger Events, Activate Relays, or Change Configuration settings. A computer can take over a Reactor or a Reactor can operate autonomously (without a computer).
Once a Reactor is configured, the Reactor monitors inputs. When inputs reach user-defined limits, relays can turn on or off. Reactors allow much more than simple relay control. Reactor inputs can trigger timers and rotations. A timer allows a relay to activate over a duration of time. A rotation is a simple counter, in which relays can be assigned to each "count". This allows powerful functions such as relay activation sequencing, flashing, and stepping. Event Piping allows timers and rotations to trigger other timers and rotations. This is very powerful for setting up complex relay activation sequences.
Mounts as a COM Port
This ProXR series controller connects to the USB port of your computer and will mount as a COM port on your PC. USB Drivers will most likely be needed and can be found in the resources section to the right and will also be available in the Base Station Software. Windows 7 & 8 users will automatically download and install the necessary drivers.
This board is equipped with a ZUSB Module. The ZUSB communications module adds USB communications to the board. The ZUSB module is powered from the USB port of your computer and includes a 6' USB Cable. The board itself will require 12 volts of power and can be hard wired or you can purchase a "wall wart" type Power Supply at checkout.
8 Inputs Available
Reactor Inputs play a vital role in the use of a Reactor controller. Analog inputs are simply inputs that are sensitive to voltages. Analog Inputs are capable of reading switches and sensors operating in the 0 to 5VDC range. Once configured, the Reactor CPU is constantly monitoring external sensors using 8 analog inputs that can read switches, resistance changes, or voltages from 0 to 5VDC. Inputs can be configured to trigger relays, relay timers and relay activation sequences.
Input Voltage Changes
Analog Inputs are very special in that they are sensitive to voltage changes. In the case of a Reactor controller, analog inputs have an 8-bit resolution, meaning the voltage input (from 0 to 5VDC) is interpreted as a value from 0 to 255.
A voltage input of 0 Volts is interpreted as a value of 0
A voltage input of 2.5 Volts is interpreted as a value of 128
A voltage input of 5 Volts is interpreted as a value of 255
So if you divide 5 Volts by 256 possible steps (0-255 for 8-Bit resolution), the Reactor controller is sensitive to voltage changes as small as 0.0195 Volts. A Reactor controller has 8 inputs. Each input is capable of reading a separate voltage from 0 to 5 VDC, provided all voltages can share a common ground. You configure exactly what value you want the board to trigger the relay or start a sequence or delay!
Who’s Qualified to Use the Reactor Series?
Some computer skills required. The Reactor Relays do not require programming, simply configure the device with the included Base Station Software. While programming is not required and simple functions can be done rather easily with basic computer skills, complex events can be configured which will require some understanding and patience.
Perhaps the most overlooked aspect of relay control is proper handling of inductive loads. Inductive loads can best be defined as anything with a magnetic coil, such as a motor, solenoid, or a transformer. Controlling a inductive load using this relay controller requires the use of induction suppression capacitors. The purpose of this capacitor is to absorb the high voltages generated by inductive loads, blocking them from the contacts of the relay. Without this capacitor, the lifespan of the relay will be greatly reduced. Induction can be so severe that it electrically interferes with the microprocessor logic of our controllers, causing relay banks to shut themselves down unexpectedly. In the case of USB devices, customers may experience loss of communications until the device is reconnected to the USB port. Capacitors that we offer are available at checkout, for more information view our Induction Suppression Video.
Base Station Software
Base Station will assist you in learning how this device functions and is the ultimate reference tool for configuring, testing and controlling this device. Base Station software supports every feature of this device - no other controller manufacturer even comes close to offering this type of software. Base Station works by communicating with your controller to identify the model and provides the appropriate graphical user interface for setting up and testing the identified device. All Reactor configurations will be made through Base Station and an overview will be discussed below. To help you get started and learn this controller Quick Start Guides are available for just about every feature. As you discover a feature in Base Station a link is provided where you can easily download the Quick Start Guide.
Configure Each Input
The Reactor Relay allows users to define the activation of a relay or an event
based on the voltage readings of the analog inputs. An input can trigger a relay directly or an input can trigger an
event, such as a timer. If an input triggers a relay, the relay may turn on. If an input triggers a timer event, a timer may be started,
but a relay may or may not be turned on based on how you have configured the controller (the time delay may be before the relay triggers). Triggering an event does not mean you are triggering a relay, it just means you are triggering an internal function. Relays may be associated
with this internal function to achieve a large number of possible operations.
Using Input Values
Reading from Left to right, the settings above indicate Input 1 will trigger a relay when Analog Input 1 is above 200. We have defined that a relay will turn on when the input level is defined by a value of 200.
In the above example, a relay is triggered when an analog input is inside a set range between 100 and 202. By defining two limits, you can further narrow the parameters for the activation of a relay. The limits can also be assigned to set the relay to be activated outside two set limits.
The configuration software makes it easy to configure each relay. Relays or multiple relays can be can be assigned to each input.
Reactor controllers have up to 8 relays available depending on the actual model selected. Each relay can be assigned to a different input or event. In the example shown below, Relay 1 is Controlled by Input 1 directly. Input 1 will turn Relay 1 ON. In order for Relay 1 to activate, it must meet the conditions of the Input 1 configuration using the settings on the Input Configuration tab (see above).
There are many ways to directly control a relay from an input. Relays 1-5 in the below example shows how inputs can turn relays
on, off, toggle relay state, set the relay to match the state of the input, or set the relay to NOT equal the state of a input.
In the example below, Relay 6 is controlled by Timer 1. In other words, if Timer 1 is active, the relay will stay ON. Otherwise, the relay will turn off. This is a great way to activate a light for a given period of time. If you are interested in Time Delay Relay, timers will be discussed on our Time Delay Relay Page.
Many More Options
We have just touched on the many ways the Reactor board can be configured. The applications that this board can be use in are extensive. For a more detailed look at the configuration and setup you can look at the Reactor Series Quick Start Guide.
Attention: 0 - 5 Volt DC Input Only
Please Note: Analog inputs can accept voltages from 0 to 5VDC ONLY. Higher voltages and negative voltages will damage the Reactor controller. Improper use of these inputs can cause irreparable damage to the board.
In this tab we'll take a look at the Reactor board design itself. The Reactor series controllers are machine manufactured for a highly accurate and reliable design. Fully tested before they leave the production facility each Reactor controller is ready to stand up to rigorous demands from heat, cold or vibration. The best test of all is the numerous boards in the field from customers all over the world in all sorts of conditions. Take it from us, these controllers will hold up!
Break-A-Way Tabs for a Smaller Design
The Reactor relays have a great feature where space is a premium - Break-A-Way Tabs. The Break-A-Way Tabs allow most boards to fit in an optional undrilled plastic enclosure. Snap off the Break-A-Way Tabs and you have a controller with a smaller profile when you need to fit in a tight space.
The Reactor Series controllers are not expandable.
SPDT Relay Installed
This device has SPDT relays installed. SPDT Single Pole Double Throw Relays have three connections - Common, Normally Open, and Normally Closed. When the relay is off, the common is connected to the normally closed connection of the relay. When the relay coil is energized, the Common swings over to the Normally Open Connection of the Relay. You can wire the device you are switching to either the Normally Open or the Normally Closed position.
ProXR series controllers are designed for long life, you should expect to get years of service from your controller and literally 2-million cycles from the relays on board. With a 5-year warranty and a money back guarantee you have nothing to loose! Place your order now, while everything is in front of you.
This board is led free and RoHS Compliant. If your requirements are for RoHS compliant parts this board is manufactured with RoHS compliant led free parts and solder.
30-Day Warranty/Money Back Guarantee
ProXR Lite series controllers are guaranteed against manufacturing and functionality defects for a full 30 days! Not to mention a 30-day money back guarantee! If for any reason you are not happy with a relay purchased from Relay Pros, simply return it within 30 days and we will give you your money back! Controllers that are damaged by our customers will not of course be warranted under any circumstances.
The boards sold are brand new units shipped from our office conveniently located in Missouri. These boards are completely tested before they are released for shipping With so many boards on our site it is impossible to stock boards, please allow two to three days production time for your order to ship. If you have any questions please feel free to call our office at 800-960-4287 or e-mail us at firstname.lastname@example.org.
Sensor Control Is Here!
Trigger relays with a sensor with and configure with included Base Station software. Here's a lists of great features:
User Friendly Software
Point & Click Interface - No Programming Knowledge Required
Override Sensor When Computer is Connected to Board
Read Sensor Levels in Base Station
Read Status of Relays in Base Station
User Friendly Board Design
8 Analog Sensor Inputs Available (0 to 5 Volt Only)
Break-A-Way Tabs lets you decide the board's size
Screw terminal or direct relay connections make connecting to the relays easy
Power Supply Available
Reliable Power Means Reliable Switching
The PWR12 is regulated power supply providing clean power necessary for
the performance of these boards. The PWR12 US power supply is a 120VAC to 12VDC 1.25A 60Hz regulated
power supply and it plugs into the barrel connector on the board. The output connector is a 2.1mm I.D. x 5.5mm
O.D. x 9.5mm R/A barrel connector.
The SR171B Enclosure is an undrilled, non-waterproof enclosure and is available at checkout for this controller.
Spec Sheet and Drawings:
an inductive load using our relay controllers requires the use of induction suppression capacitors. The purpose of this capacitor
is to absorb the high voltages generated by inductive loads, blocking them from the contacts of the relay. Without this capacitor,
the lifespan of the relay will be greatly reduced. Induction can be so severe that it electrically interferes with the microprocessor
logic of our controllers, causing relay banks to shut themselves down unexpectedly.
Reactor boards are configured
using Base Station Software (a free download). Using a point-and-click interface for configuration means you can accomplish automation tasks in minutes.
There are no programming languages to learn.
Data Sheets & Quick Start Guides
Below are the Data Sheets Quick Start Guides for this board. These are the guides that will help you communicate and
configure this board.