PVC Overmolded Remote Room Thermostat Warming Heating Cable Undefloor Micro Temperature Sensor Probe 10KΩ 3950K 6.5x25mm
Brand Name:Aolittel
Model Number:CWFM0103FC1-202M113X
Minimum Order Quantity:1000 Pieces
Delivery Time:2-4 Weeks
Payment Terms:T/T
Price:Negotiable
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Dongguan Guangdong China
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NO.27,Jinlanling Street,Taigongling Village Dongguan 523829,Guangdong,China
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Product Details
PVC Overmolded Remote Room Thermostat Warming Heating Cable Undefloor Micro Temperature Sensor Probe 10KΩ 3950K 6.5x25mm
Overview
The Probe and Sensor are used to control temperature where moisture would be a problem i.e. in wet room or bathroom. It can also control floor temperature where overheating would cause damage.
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Materials
| NO | Material Name | Material and Specifications |
| 1. | Element | R25=10KΩ±1% B25/50=3950K±1% DC |
| 2. | Coating | NTC encapsulated using PVC over-mold material (White) |
| 3 | Cable features | UL2464-22AWG Tin plated copper cable with white PVC flat jacket wire 80℃ 300V |
| 4. | Wire ends | Tinned |
Dimension (mm)
| Dimension | ||||
| A | B | C | D | L |
| 6.5 | 20 | 25±5 | 3±1 | as required |
Performances
| NO | Item | Sign | Test Conditions | Min. | Nor. | Max. | Unit |
| 1. | Resistance at 25℃ | R25 | Ta=25±0.05℃ PT≦0.1mw | 9.9 | 10.0 | 10.1 | kΩ |
| 2. | B Value | B25/50 | 3910.5 | 3950 | 3989.5 | k | |
| 3. | Dissipation factor | σ | In still air | About 2 | mW/℃ | ||
| 4. | Time response | τ | In flowing water | About 15 | sec | ||
| 5. | Withstanding Voltage | / | 1500VAC 2Sec | No breakdown | Sec | ||
| 6. | Insulation Resistance | 500VDC | ≧100 | MΩ | |||
| 7. | Operating temp. range | / | / | -30 | / | +105 | ℃ |
Dry & Solid Wall Instalation
Minco Heat 0.5M2 Twin-Conductor Electric Underfloor Heating Mats For Warm Floor, Underfloor Heating Kits
Resistance Vs. Temperature Table
| R-T CONVERSION TABLE | ||||||||
| R25=10KΩ±1% B25/50=3950K±1% | ||||||||
| T/℃ | Rmin | Rcen | Rmax | T/℃ | Rmin | Rcen | Rmax | |
| -40 | 335.811 | 351.495 | 367.875 | -5 | 41.735 | 42.774 | 43.834 | |
| -39 | 314.029 | 328.472 | 343.546 | -4 | 39.599 | 40.563 | 41.547 | |
| -38 | 293.803 | 307.110 | 320.988 | -3 | 37.586 | 38.480 | 39.392 | |
| -37 | 275.015 | 287.279 | 300.060 | -2 | 35.686 | 36.517 | 37.363 | |
| -36 | 257.552 | 268.859 | 280.635 | -1 | 33.894 | 34.665 | 35.450 | |
| -35 | 241.313 | 251.741 | 262.595 | 0 | 32.203 | 32.919 | 33.646 | |
| -34 | 226.204 | 235.826 | 245.832 | 1 | 30.607 | 31.270 | 31.945 | |
| -33 | 212.141 | 221.021 | 230.250 | 2 | 29.099 | 29.715 | 30.340 | |
| -32 | 199.044 | 207.242 | 215.757 | 3 | 27.674 | 28.246 | 28.826 | |
| -31 | 186.841 | 194.412 | 202.270 | 4 | 26.328 | 26.858 | 27.396 | |
| -30 | 175.465 | 182.460 | 189.714 | 5 | 25.055 | 25.547 | 26.045 | |
| -29 | 164.856 | 171.320 | 178.019 | 6 | 23.851 | 24.307 | 24.769 | |
| -28 | 154.957 | 160.932 | 167.120 | 7 | 22.712 | 23.135 | 23.563 | |
| -27 | 145.716 | 151.241 | 156.959 | 8 | 21.634 | 22.026 | 22.423 | |
| -26 | 137.086 | 142.196 | 147.481 | 9 | 20.614 | 20.977 | 21.345 | |
| -25 | 129.022 | 133.750 | 138.636 | 10 | 19.650 | 19.987 | 20.327 | |
| -24 | 121.485 | 125.859 | 130.378 | 11 | 18.733 | 19.044 | 19.359 | |
| -23 | 114.435 | 118.485 | 122.665 | 12 | 17.865 | 18.154 | 18.445 | |
| -22 | 107.840 | 111.589 | 115.457 | 13 | 17.043 | 17.310 | 17.579 | |
| -21 | 101.667 | 105.139 | 108.718 | 14 | 16.264 | 16.510 | 16.759 | |
| -20 | 95.886 | 99.102 | 102.415 | 15 | 15.524 | 15.752 | 15.982 | |
| -19 | 90.471 | 93.450 | 96.518 | 16 | 14.823 | 15.034 | 15.246 | |
| -18 | 85.395 | 88.156 | 90.997 | 17 | 14.157 | 14.352 | 14.548 | |
| -17 | 80.636 | 83.195 | 85.826 | 18 | 13.525 | 13.705 | 13.885 | |
| -16 | 76.173 | 78.544 | 80.982 | 19 | 12.925 | 13.090 | 13.257 | |
| -15 | 71.984 | 74.183 | 76.441 | 20 | 12.354 | 12.507 | 12.660 | |
| -14 | 68.052 | 70.091 | 72.184 | 21 | 11.813 | 11.953 | 12.094 | |
| -13 | 64.359 | 66.250 | 68.189 | 22 | 11.298 | 11.427 | 11.557 | |
| -12 | 60.889 | 62.643 | 64.441 | 23 | 10.808 | 10.927 | 11.046 | |
| -11 | 57.628 | 59.255 | 60.922 | 24 | 10.342 | 10.452 | 10.561 | |
| -10 | 54.562 | 56.071 | 57.617 | 25 | 9.900 | 10.000 | 10.100 | |
| -9 | 51.677 | 53.078 | 54.511 | 26 | 9.470 | 9.570 | 9.670 | |
| -8 | 48.963 | 50.263 | 51.592 | 27 | 9.061 | 9.161 | 9.260 | |
| -7 | 46.408 | 47.614 | 48.847 | 28 | 8.672 | 8.771 | 8.871 | |
| -6 | 44.002 | 45.121 | 46.264 | 29 | 8.302 | 8.401 | 8.499 | |
| R-T CONVERSION TABLE | ||||||||
| R25=10KΩ±1% B25/50=3950K±1% | ||||||||
| T/℃ | Rmin | Rcen | Rmax | T/℃ | Rmin | Rcen | Rmax | |
| 30 | 7.950 | 8.048 | 8.146 | 67 | 1.881 | 1.932 | 1.984 | |
| 31 | 7.615 | 7.712 | 7.809 | 68 | 1.817 | 1.866 | 1.917 | |
| 32 | 7.295 | 7.391 | 7.488 | 69 | 1.754 | 1.803 | 1.852 | |
| 33 | 6.991 | 7.086 | 7.182 | 70 | 1.695 | 1.742 | 1.790 | |
| 34 | 6.702 | 6.795 | 6.890 | 71 | 1.637 | 1.684 | 1.731 | |
| 35 | 6.425 | 6.518 | 6.612 | 72 | 1.582 | 1.627 | 1.674 | |
| 36 | 6.162 | 6.254 | 6.346 | 73 | 1.529 | 1.573 | 1.619 | |
| 37 | 5.911 | 6.001 | 6.092 | 74 | 1.478 | 1.521 | 1.566 | |
| 38 | 5.672 | 5.761 | 5.850 | 75 | 1.429 | 1.471 | 1.515 | |
| 39 | 5.443 | 5.531 | 5.619 | 76 | 1.382 | 1.423 | 1.466 | |
| 40 | 5.225 | 5.311 | 5.398 | 77 | 1.336 | 1.377 | 1.419 | |
| 41 | 5.017 | 5.102 | 5.188 | 78 | 1.293 | 1.332 | 1.373 | |
| 42 | 4.818 | 4.902 | 4.986 | 79 | 1.251 | 1.289 | 1.329 | |
| 43 | 4.628 | 4.710 | 4.794 | 80 | 1.210 | 1.248 | 1.287 | |
| 44 | 4.447 | 4.528 | 4.609 | 81 | 1.171 | 1.208 | 1.246 | |
| 45 | 4.274 | 4.353 | 4.433 | 82 | 1.134 | 1.170 | 1.207 | |
| 46 | 4.108 | 4.186 | 4.265 | 83 | 1.098 | 1.133 | 1.170 | |
| 47 | 3.950 | 4.026 | 4.104 | 84 | 1.063 | 1.097 | 1.133 | |
| 48 | 3.799 | 3.874 | 3.950 | 85 | 1.029 | 1.063 | 1.098 | |
| 49 | 3.654 | 3.728 | 3.802 | 86 | 0.997 | 1.030 | 1.064 | |
| 50 | 3.515 | 3.588 | 3.661 | 87 | 0.966 | 0.998 | 1.032 | |
| 51 | 3.383 | 3.454 | 3.526 | 88 | 0.936 | 0.968 | 1.000 | |
| 52 | 3.256 | 3.326 | 3.396 | 89 | 0.907 | 0.938 | 0.970 | |
| 53 | 3.135 | 3.203 | 3.272 | 90 | 0.879 | 0.909 | 0.941 | |
| 54 | 3.019 | 3.085 | 3.153 | 91 | 0.852 | 0.882 | 0.912 | |
| 55 | 2.907 | 2.973 | 3.039 | 92 | 0.826 | 0.855 | 0.885 | |
| 56 | 2.801 | 2.865 | 2.930 | 93 | 0.801 | 0.829 | 0.859 | |
| 57 | 2.699 | 2.761 | 2.825 | 94 | 0.777 | 0.805 | 0.833 | |
| 58 | 2.601 | 2.662 | 2.724 | 95 | 0.753 | 0.781 | 0.809 | |
| 59 | 2.507 | 2.567 | 2.628 | 96 | 0.731 | 0.758 | 0.785 | |
| 60 | 2.417 | 2.476 | 2.535 | 97 | 0.709 | 0.735 | 0.762 | |
| 61 | 2.330 | 2.388 | 2.447 | 98 | 0.688 | 0.714 | 0.740 | |
| 62 | 2.248 | 2.304 | 2.361 | 99 | 0.668 | 0.693 | 0.719 | |
| 63 | 2.168 | 2.223 | 2.280 | 100 | 0.648 | 0.673 | 0.698 | |
| 64 | 2.092 | 2.146 | 2.201 | 101 | 0.629 | 0.653 | 0.678 | |
| 65 | 2.019 | 2.072 | 2.126 | 102 | 0.611 | 0.635 | 0.659 | |
| 66 | 1.949 | 2.000 | 2.053 | 103 | 0.593 | 0.616 | 0.640 | |
What is the floor sensor probe and how does it work?
Every aolittel electric underfloor heating thermostat should be configured to use an in-floor sensor probe to monitor the temperature of the floor. This is the most accurate way to control the running temperatures and positively influence your energy bills.
The sensor probe is 3m long, 4mm thick and should be laid within a conduit, in a groove in the floor or insulation board. You can extend the sensor cable (using a 0.75mm twin core flex) by up to 50m.
The conduit has a diameter of 11mm and should be used to facilitate removal or replacement if required.
Sensor probes should always be installed in a clear area of the floor (internal doorways are a good spot) away from any other hot or cold influence such as hot water pipes or large glazed elevations and never under a rug! Rugs act as an insulator, keeping the heat in the floor and raising the temperature.
If you cover the sensor probe with a rug the rest of the floor will stay cold because the thermostat is only monitoring the hottest part of the floor.
The actual sensor is inside the module on the end of the cable and works by constantly monitoring the temperature of the floor.
The temperature data is sent back to the thermostat which, when working to a preset schedule, automatically maintains your desired floor temperature.
3 Tips for Installing a Floor Sensor
When it comes to installing a floor-heating system, most of the
attention goes to laying out the heating cable. Whether you’re
using plastic fixing strips to weave the cable back and forth
across the room, you’re pushing the cable into an installation
membrane, or your system comes pre-assembled on mesh fabric, about
95 percent of the effort goes into installing the cable. The other
5 percent goes into hooking up the thermostat and installing the
floor sensor. And though it’s clear what a floor sensor does —
provides an accurate reading of the floor temperature to the
thermostat so that it can regulate the system — how it works takes
a little bit more research.Your floor-heating system’s installation
manual will have all the details on how to correctly install the
floor sensor. For instance, it will explain that the floor sensor
does not have to reach the middle of the room to get the most
accurate floor temperature reading. It only needs to reach about 6
inches into the system, running parallel with (and never
overlapping) the heating cable. However, there are a few
installation tips that you might not find in your manual that would
help to know ahead of time.
Tip #1: Install two floor sensors.When it comes to in-floor
heating, it’s better to be proactive than reactive if you can.
That’s why WarmlyYours suggests installing two floor sensors — but
only connecting one to the thermostat. That way, if your floor
sensor fails, you have a backup already installed that you can
simply connect to the back of the thermostat. Backup/replacement
floor sensors are available for purchase on www.warmlyyours.com for
just $10. Although floor sensors very rarely fail, installing two
instead of one will keep you from having to make a repair in the
case that you do encounter a failure.
Tip #2: Make use of the underlayment.The floor sensor is thicker
than the heating element. Nevertheless, when installing a
floor-heating system under tile or stone, the floor sensor nestles
in nicely next to the heating element without adding to the floor
elevation because the thinset provides a thick enough cushion
between the heating element and the flooring. However,
floor-heating systems installed under carpet or laminate do not use
thinset. The heating element sits directly against the flooring
material. As a result, the floor sensor will be situated higher
than the heating cable, causing a bump in your flooring if you
don’t fix the issue. The best way to solve this problem is to cut a
channel in the underlayment located beneath your floor-heating
system. This will allow the floor sensor to get an accurate reading
without adding to the floor elevation.
Tip #3: Use the grout joint for repairs.If you have a floor-heating
system installed under a tile or stone floor and the floor sensor
fails, your grout joints can help! It’s possible to retrofit a
replacement floor sensor into the grout joint and then grout over
it. This will prevent you from having to tear up any tile to repair
the sensor.A complimentary floor sensor is included with the
purchase of any nSpiration thermostat. In the thermostat settings,
users can select their flooring type or even enter a custom
temperature range to ensure that the floor temperature does not
exceed the manufacturer’s recommended limits.
PVC Overmolded Remote Room Thermostat Warming Heating Cable Undefloor Micro Temperature Sensor Probe 10KΩ 3950K 6.5x25mm
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