It pulls air from the back of the tractor, where your legs are. Kubota claims the reason they did it like that is so on hot summer days, you wouldn't be getting blasted with hot air.
Kubota tractor overheating when fan replaced to electric. (Kubota G1900S (D722))
- Thread starter jacoBiceps
- Start date
dvcochran
Active member
Equipment
Kubota M9000, New Holland TN90, Deere 2640, Vermeer 504N, Vermeer 504SI, more
Is that an addon speed controller in the photo?
Is that an addon speed controller in the photo?
GreensvilleJay
Well-known member
Equipment
BX23-S,57 A-C D-14,58 A-C D-14, 57 A-C D-14,tiller,cults,Millcreek 25G spreader,
yes, he added the PWM speed controller to slow down the fan BUT not all '12 volt electric motors' respond well to PWM.
I'll assume he bench tested it for 5-6 hrs, different speeds to be 100% sure it would work as required. If the controller isn't rated for 30 amps ( x2 the fan's spec) AND mounted on a big steel plate or in the airflow, it can overheat and go 'funny'.... seen THAT several times in the past...
I'll assume he bench tested it for 5-6 hrs, different speeds to be 100% sure it would work as required. If the controller isn't rated for 30 amps ( x2 the fan's spec) AND mounted on a big steel plate or in the airflow, it can overheat and go 'funny'.... seen THAT several times in the past...
Caveat: Have not read earlier responses.
Return it to OEM specs and see if the overheating issue goes away.
If so, you've found your problem.
My 2006 GMC Sierra 4wd 5.3 high output came stock with 2 electric fans. One ran when the air conditioner was on, the other if temperature exceeded a set mark. In 160K miles, I heard the second fan come on once, I was stuck in traffic in 100 plus degree heat with the air on high for almost an hour. The temp gauge never strayed a half of a needle above or below center, no matter what I was pulling or the temperature outside. There is more to making an electric fan work than just slapping one on and connecting a wire or two.
Yes, but I can mow the lawn in an air conditioned cab with radio on and a beer in hand.
If I remember right the mid 80's Audi 5000 had 2 engines both 5 cylinders(2.2 liters) with a radiator at a 30 degree angle behind the drivers head light. The NA and the turbo used the same radiator, but the turbocharged engine also had a additional radiator(no fan behind it) plumbed into the coolant system. This additional radiator was the size of a heater core and mounted behind the grill. Is it possible to do the same on your tractor? If your doing all this just for the sound of a turbo have you thought about a battery electric vehicle pedestrian noise maker?
There's your problem. You buggered up the shroud! the tip of the fan is working in separated air. That shroud's shape is important.
At 180 watts (or 108 since both numbers appeared in the thread), that electric fan motor is capable of developing a small fraction of a horsepower and is probably just too small for the job compared to the mechanical fan. If the electric motor were 100% efficient, and it is NOT, then it could develop just under 1/4 HP at a 180 watt draw. Electric vehicle fans tend to do a poor job of working against high back or suction pressure and airflow efficiency drops very quickly under these conditions.
Cars in the 300HP range get away with a 500-600 watt fan BUT they have a large free airflow radiator and shroud system that was designed from the start for the electric fan. And most of the time the airflow is provided by high road speed, unlike a tractor they aren't running for long periods of time at full power and 2 MPH.
Rodger
Cars in the 300HP range get away with a 500-600 watt fan BUT they have a large free airflow radiator and shroud system that was designed from the start for the electric fan. And most of the time the airflow is provided by high road speed, unlike a tractor they aren't running for long periods of time at full power and 2 MPH.
Rodger
GreensvilleJay
Well-known member
Equipment
BX23-S,57 A-C D-14,58 A-C D-14, 57 A-C D-14,tiller,cults,Millcreek 25G spreader,
re: is probably just too small for the job compared to the mechanical fan.
not necessarily. So far ZERO info on the CFM the mechanical fan setup actually produces. The electric one has a spec of 802CFM. It'd be nice to see the spec for the OEM fan setup, only then can we compare 'apples to apples'.
not necessarily. So far ZERO info on the CFM the mechanical fan setup actually produces. The electric one has a spec of 802CFM. It'd be nice to see the spec for the OEM fan setup, only then can we compare 'apples to apples'.
Jay,
For the CFM number to be comparable, they would have to be specified under the same conditions. If Kubota engineering was willing to share the rated CFM of the stock mechanical fan it would be the actual airflow within that cooling system at a specified (generally rated) RPM. The aftermarket electric fan CFM static flow spec is generally far greater than what it will actually do with the real world pressure drop as part of the actual screens/radiator/shroud in this actual application.
Low power fans can produce very large airflow when there is negligible flow resistance but fans designed to have less performance drop under high flow resistance will typically use more aggressive blade geometry and often a higher RPM motor.
One of the alternatives to clutch type fans used by some of the automotive companies in the 70s were "flex fans" with blades that became less aggressive at high RPM to reduce noise and power draw. And electric fans are great in a lot of applications where packaging and cost are prime considerations but for this tractor application, a proper mechanical fan setup is still the most practical. If someone has a tractor dyno handy, do a very fast run with the mechanical fan mounted and removed to see how much HP it takes at rated RPM and I expect most would be surprised by the number but it takes a lot of power to move air with the airflow resistance of the cooling system. I remember seeing the specs for my GMC diesel pickup and the fan consumes close to 15 HP at governed RPM with the electric fan clutch fully engaged. The smaller fan on a Kubota tractor isn't close to this but it will be a lot more than the actual developed HP of a small electric fan motor.
Rodger
For the CFM number to be comparable, they would have to be specified under the same conditions. If Kubota engineering was willing to share the rated CFM of the stock mechanical fan it would be the actual airflow within that cooling system at a specified (generally rated) RPM. The aftermarket electric fan CFM static flow spec is generally far greater than what it will actually do with the real world pressure drop as part of the actual screens/radiator/shroud in this actual application.
Low power fans can produce very large airflow when there is negligible flow resistance but fans designed to have less performance drop under high flow resistance will typically use more aggressive blade geometry and often a higher RPM motor.
One of the alternatives to clutch type fans used by some of the automotive companies in the 70s were "flex fans" with blades that became less aggressive at high RPM to reduce noise and power draw. And electric fans are great in a lot of applications where packaging and cost are prime considerations but for this tractor application, a proper mechanical fan setup is still the most practical. If someone has a tractor dyno handy, do a very fast run with the mechanical fan mounted and removed to see how much HP it takes at rated RPM and I expect most would be surprised by the number but it takes a lot of power to move air with the airflow resistance of the cooling system. I remember seeing the specs for my GMC diesel pickup and the fan consumes close to 15 HP at governed RPM with the electric fan clutch fully engaged. The smaller fan on a Kubota tractor isn't close to this but it will be a lot more than the actual developed HP of a small electric fan motor.
Rodger
GreensvilleJay
Well-known member
Equipment
BX23-S,57 A-C D-14,58 A-C D-14, 57 A-C D-14,tiller,cults,Millcreek 25G spreader,
If I was really,really, really curious about this all I'd need is the fan dimensions and RPM. One of my clients made fans (ok huge 'industrial' ones ) but he gave me several programs used to design them. That code is on an old Windows98 machine 'somewhere' in the basement,yeesh gotta be 2 decades old... At the time we were both intersted in modifying the code for variable pitch.... Probably some fancy 'online- fill-in-the-blanks' ap available these days....
It would take a complex set of inputs to accurately model airflow under different air resistance and RPM conditions. Blade geometry is critical and can be optimized for many parameters such as quiet, low power draw, high low static airflow, low performance drop under high static, etc. but not simultaneously for all of these parameters. Blade contour, edge "finish", shape and finish of frame/shroud can all create dirty airflow under differing airflow conditions.
Kubota and their supplier would have spent some quality design time choosing the proper setup, aftermarket setups aren't so carefully match making Bona Fortuna (good luck) a factor in typical user mods. The tractor was designed as a holistic system with multiple parts and subsystems working together, user mods that ignore this fact often result in sub-optimal results.
Below is a typical graph of real world performance for an electric fan with static pressure on the Y axis and delivered airflow on the X axis. Of note is that there is a rapid dropoff in delivered CFM which falls rapidly reaching cutoff at a fairly low back pressure. And the relationship lines aren't straight because of the interactive effects within the system. Axial fans will always have a fast drop in performance under increasing back pressure but they can be designed to work sufficiently under these conditions which is how Kubota set up the original cooling system. Centrifugal blowers can be designed to deliver a lot of CFM under high back (or intake) pressure but they aren't really practical for this type of cooling system.
Rodger
Kubota and their supplier would have spent some quality design time choosing the proper setup, aftermarket setups aren't so carefully match making Bona Fortuna (good luck) a factor in typical user mods. The tractor was designed as a holistic system with multiple parts and subsystems working together, user mods that ignore this fact often result in sub-optimal results.
Below is a typical graph of real world performance for an electric fan with static pressure on the Y axis and delivered airflow on the X axis. Of note is that there is a rapid dropoff in delivered CFM which falls rapidly reaching cutoff at a fairly low back pressure. And the relationship lines aren't straight because of the interactive effects within the system. Axial fans will always have a fast drop in performance under increasing back pressure but they can be designed to work sufficiently under these conditions which is how Kubota set up the original cooling system. Centrifugal blowers can be designed to deliver a lot of CFM under high back (or intake) pressure but they aren't really practical for this type of cooling system.
Rodger