This application claims priority to PCT Application No. PCT/EP2016/080018, having a filing date of Dec. 7, 2016, based on European Application No. 15198477.0, having a filing date of Dec. 8, 2015, the entire contents both of which are hereby incorporated by reference.
The following relates to a method of monitoring the amount of lubricant inside a bearing of a wind turbine. Furthermore, the following relates to a bearing of a wind turbine and to a wind turbine comprising such a bearing.
Many types of bearings comprise a lubricant such as grease or oil for reducing wear and fatigue of the bearing. In particular, wear and fatigue of the rolling elements and/or the raceways of the bearing are reduced by the provision of a lubricant inside the bearing.
Some lubricated bearings require frequent, periodic maintenance to prevent premature failure. Other lubricated bearings require little maintenance, these bearings being described by terms such as “sealed bearing” or “sealed for life”. A sealed bearing comprises a seal such as a rubber lip which avoids or minimizes as best as possible leakage of the lubricant from inside the bearing to the ambient.
In practice, however, a certain leakage of lubricant out of the bearing has often to be accepted. This has the consequence that the amount of lubricant inside the bearing decreases over the time. This in return makes a refill of lubricant necessary from time to time.
A highly relevant question regarding timing and planning the moment to refill lubricant into the bearing is the question how large the amount of lubricant that exists inside the bearing actually is. Unfortunately, it is quite difficult to determine the amount of lubricant inside a bearing. In other words, it is difficult to determine the filling level of lubricant inside a bearing.
In the related art, determination of the filling level of lubricant has to be carried out manually by a service personnel examining the bearing. For large industrial type bearings, this is often done endoscopically. This, however, means that specialized service personnel is possibly needed. Furthermore, frequent visits for inspection of the bearing in order to determine the filling level of lubricant inside the bearing is costly.
Another approach in the related art is to ignore the actual filling level of lubricant inside a bearing, and instead to carry out a refill of lubricant in predefined intervals. This has the disadvantage that suboptimally timed service visits for refilling the bearing is made. Particularly for bearings of a wind turbine, with the wind turbine being located at a site which is difficult to access, unnecessary service visits for refilling lubricant into a bearing are costly. Sites which are difficult to access are, for example, offshore sites or sites at remote and/or mountainous regions.
Finally note that a delayed refill of lubricant to a bearing may cause considerable costs due to wear. Thus, a bearing which is operated at critically low filling levels of lubricant may cause considerable repair costs.
An aspect relates to monitoring the amount of lubricant inside a bearing of a wind turbine in a simple and reliable manner.
According to embodiments of the invention, there is provided a method of monitoring the amount of lubricant inside a bearing of a wind turbine, wherein the bearing comprises a lubricant for reducing wear and fatigue of the bearing, a seal for minimizing the amount of lubricant which is leaking out of the bearing, and a ventilation device with at least one pressure compensation hole for enabling a pressure compensation between the sealed bearing and the ambient. Furthermore, the bearing comprises a lubricant drain hole for enabling lubricant to exit the bearing in a controlled manner. The method comprises the steps of blowing a compressed medium through the pressure compensation hole into the bearing; measuring the pressure inside the bearing; and determining the amount of lubricant inside the bearing based on the measured pressure.
The use of a lubricant and the use of a seal are standard solutions for bearings in general, cf. WO 2015/091719 A1, for instance. It is also well known to use such types of bearings for a wind turbine.
Also the provision of a lubricant drain hole in a bearing is a common option for bearings of a wind turbine. Such a lubricant drain hole has the objective to provide means for the lubricant to exit the bearing in a controlled manner. In other words, used lubricant, such as e.g. used grease, can be channeled out of the bearing and guided into, for instance, a lubricant container. Therein the used lubricant is collected and can be disposed during routine service visits of the wind turbine.
The further features of the bearing, namely the ventilation device comprising at least one pressure compensation hole is certainly not a standard solution in the state of the art for bearings of a wind turbine. The ventilation device has the objective to enable and ensure that the pressure inside the bearing and outside the bearing is substantially equal. This is advantageous because an overpressure inside the bearing has the effect that the seal is pushed in a direction such that the leakage rate of lubricant out of the bearing is increased. In other words, without a means of reducing overpressure inside the bearing, the risk of unfavorably high leakage rates is increased.
A key aspect of embodiments of the present invention is that, by the use of the pressure compensation hole, a compressed medium such as air is blown into the bearing, thus deliberately generating overpressure inside the bearing. Measuring this overpressure gives an indication about the actual filling level of lubricant inside the bearing. This indication, i.e. this insight, is gained by the fact that the pressure increase which is generated by blowing a certain, predetermined amount of compressed medium into the bearing depends significantly on the available volume of air inside the bearing.
To give a concrete example, in a first scenario one fifth of the volume inside the bearing is filled with air while four fifth of the volume is filled with lubricant. In this first scenario, a relatively high pressure increase is achieved by blowing in a predetermined amount of compressed medium. On the other hand, in a second scenario, assuming one fifth of the volume inside the bearing filled by lubricant and four fifth of the volume filled by air, a relatively small pressure increase is achieved by blowing in the same amount of compressed medium inside the bearing. By measuring the pressure inside the bearing during or after blowing in the compressed medium, the amount of lubricant inside the bearing can be determined. Thus, the amount of lubricant inside the bearing is indirectly measured.
A key advantage of the inventive method is that no visual inspection of the inside of the bearing is necessary in order to determine the amount of lubricant being present inside the bearing. Additionally, it can be imagined to automate the disclosed method steps such that the method can even be carried out remotely. This has the advantage that the filling level of the lubricant inside the bearing can even be determined and monitored remotely. Consequently, the present inventive method discloses a concept wherein determination of the amount of lubricant inside the bearing is highly simplified and improved compared to conventional methods.
In an embodiment of the invention, the pressure inside the bearing is measured in absolute values. For example, the pressure inside the bearing is determined to be 1.08 bar during or after carrying out the inventive method. Then, this measured absolute value can be compared to an initial, i.e. a default value, namely the pressure inside the bearing before the compressed medium has been blown in. In the given example, such an initial value may be one bar. Then the pressure increase inside the bearing is calculated by subtracting the initial pressure of the bearing from the measured pressure. In the given example this leads to the result of a pressure increase of 0.08 bar being caused by blowing in the compressed medium into the bearing.
In the following, two alternatives are explained, how the amount of lubricant inside the bearing may concretely be determined.
In a first alternative, the amount of lubricant inside the bearing is determined by correlating the maximum pressure increase with the amount of lubricant inside the bearing by means of a reference curve.
Specifically, the pressure increase is obtained by measuring the absolute value of the pressure inside the bearing and subtracting the initial pressure of the bearing from this measured absolute value. This pressure increase is determined continuously during blowing in the compressed medium into the bearing. Then, the maximum pressure increase is identified and this value of the maximum pressure increase is used to determine the amount of lubricant inside the bearing. This is advantageously been done by means of a reference curve. Such a reference curve, which may also be denoted as calibration curve, characterizes the dependency of the pressure increase on the amount of lubricant. This reference curve needs to be determined once for a special type of a bearing and can then be used continuously in order to translate a specific pressure increase value into an amount of lubricant being present inside the bearing. This is necessary because the inventive method is an indirect way of monitoring the amount of lubricant inside the bearing.
A second alternative to realize the determination of the amount of lubricant inside the bearing is by correlating the rate, i.e. the slope, of the time-dependent pressure increase with the amount of lubricant inside the bearing.
Specifically, a bearing with a low filling level of lubricant, i.e. with a high volume of air inside the bearing, features a smaller increase of the pressure inside the bearing compared to a bearing with a high filling level of lubricant, i.e. a small volume of air inside the bearing. Therefore, applying and blowing in a certain amount of compressed medium leads to a relatively strong and steep increase of the pressure inside the bearing in the case of a high filling level of lubricant, and leads to a relatively weak and flat increase in the case of a low filling level of lubricant.
The first alternative is specifically advantageous if it can be ensured that the volume inside the bearing is substantially sealed. In other words, there should be no or only negligible “contact” between the inside of the bearing and the ambient. Assuming that in general this sealing is realized by the seal of the bearing, it has to be only ensured only that the lubricant drain hole is actually entirely or widely blocked, i.e. covered, during determination of the filling level of the lubricant. In general this complete or almost complete blocking of the lubricant drain hole is realized if the lubricant drain hole is sufficiently small and the amount of lubricant which exits the lubricant drain hole is sufficiently high. In practice this assumption, or prerequisite, is often given at relatively high filling levels of the bearing, i.e. if relatively much lubricant is still present inside the bearing.
The second alternative is particularly interesting and advantageous when it cannot be ensured that the lubricant drain hole is completely or almost completely blocked during the whole time span when compressed medium is blown into the bearing. Assuming for example that the time span of blowing compressed medium into the bearing amounts to twenty seconds. If the lubricant drain hole is freed by pushing used lubricant out of the lubricant drain hole after, for example, ten seconds, then the measured pressure inside the bearing will probably decrease abruptly at that moment when the lubricant drain hole is freed. This is in principle undesired by the present method. At least it is undesired when the maximum pressure increase value is intended to be taken as a measure for the amount of lubricant being present inside the bearing. Still, the data during blowing of the compressed medium into the bearing from the beginning until the moment where the lubricant drain hole is freed can still be used namely by analyzing the rate, i.e. the slope, at which the pressure increases inside the bearing. In other words, the first derivative of the time-dependent pressure which is measured is analyzed and correlated to the amount of lubricant inside the bearing.
It is advantageous to use a compressor unit, which is connected with a pressure compensation hole for selectively blowing the compressed medium through the pressure compensation hole into the bearing. Experiences have shown that a time span between two seconds and sixty seconds, in particular a time span between ten seconds and thirty seconds, is advantageous for blowing in the compressed medium into the bearing.
The given values for a preferred time span are based on the finding that if the time span is chosen very small, it is difficult to monitor and observe a significant difference in the pressure increase between the case of a low filling level and the case of high filling level of lubricant inside the bearing. If, on the other side, the time span is chosen to be very large, for example larger than one minute, this has the drawback that deliberately a overpressure is created inside the bearing during a relatively long time span, which, as has been mentioned already, in principle is undesired as any overpressure inside the bearing causes an increased leakage rate of lubricant out of the bearing. Thus, a compromise has to be found between using overpressure for a limited time span in order to indirectly monitor the amount of lubricant inside the bearing, without however creating an undesired source of leakage of lubricant out of the bearing.
It is advantageous to set the pressure of the compressor unit, i.e. the pressure by which the compressed medium is blown into the bearing through the pressure compensation hole, at such a level that the impact of the counter pressure inside the bearing on the volume of compressed medium which is blown into the bearing during a specific time span is negligible. This can be achieved by choosing a sufficiently high pressure provided by the compressor unit. To give a concrete example, if the pressure inside the bearing is in the range between 1.0 bar and 1.3 bar, injecting the compressed medium into the bearing with a pressure of at least 2.0 bar ensures that substantially the same volume of compressed air is injected into the bearing, regardless whether the pressure inside the bearing is at the lower limit or the upper limit of the range of pressures given above.
In an advantageous embodiment, the bearing further comprises at least one drain hole valve for selectively shutting the lubricant drain hole. By having such a valve for deliberately shutting, i.e. closing the lubricant drain hole, the method can be amended advantageously by the further steps of shutting the lubricant drain hole by means of the drain hole valve during blowing the compressed medium through the pressure compensation hole—and opening the lubricant drain hole by means of the drain hole valve after having measured the pressure inside the bearing.
A key aspect of such a drain hole valve is that by activating, i.e. deliberately shutting the lubricant drain hole, the analysis is not dependent on the assumption that the lubricant drain hole remains blocked by used lubricant during the entire period of blowing compressed medium into the bearing. In other words, providing such a drain hole valve still makes it possible to apply the second alternative of determining the amount of lubricant inside the bearing by evaluating the rate or the slope of the pressure increase, but such a drain hole valve also enables a reliable use of the first alternative, namely evaluating the maximum pressure increase inside the bearing and correlating that value with the filling level of lubricant inside the bearing. Thus, it makes the monitoring more flexible and more reliable.
Furthermore, provision of such a drain hole valve is advantageous as it only signifies a minimum constructional detail to be added. Additionally, such valves are a standard device, which are inexpensive to procure and easy to add to the existing bearing.
Such a drain hole valve may be controlled pneumatically, hydraulically and/or electrically. In principle, it could even be controlled mechanically. Activation of the valve is advantageously carried out remotely.
Furthermore, the drain hole valve can be controlled actively or passively. An example of a passively controlled valve is a preloaded valve, e.g. preloaded by a mechanical spring, which closes the lubricant drain hole in a default state and opens it only at a predetermined pressure, e.g. an overpressure of 0.15 bar.
In a further embodiment, activation of the drain hole valve is carried out automatically and could be included into the general wind turbine controller, making operation of the wind turbine safer and service and maintenance work more efficient.
As a first option, in the case of a warning due to a low filling level of lubricant inside the bearing, e.g. the main bearing of the wind turbine, an automatic lubrication system can be programmed to speed up injection of fresh lubricant by pumping in a predetermined amount, e.g. twenty liter, of lubricant, e.g. grease, into the bearing.
As a second option, in the case of a warning due to a low filling level of lubricant inside the main bearing of the wind turbine, the drain hole valve could be programmed to shut and thus closing the lubricant drain hole completely. This would result in reduced further loss of lubricant out of the bearing—as the loss of lubricant is defined as the sum of leakage through seals and through drain holes—until refill of the bearing by fresh lubricant has been carried out.
The embodiment is furthermore related towards a bearing of a wind turbine, wherein the bearing comprises a lubricant for reducing wear and fatigue of the bearing, a seal for minimizing the amount of lubricant which is leaking out of the bearing and a ventilation device with at least one pressure compensation hole for enabling a pressure compensation between the sealed bearing and the ambient. Furthermore, the bearing is characterized in that the ventilation device comprises a compressor unit, which is connected with a pressure compensation hole such that a compressed medium can be selectively blown through the pressure compensation hole into the bearing.
As it has been described in detail during disclosure of the inventive method, such a bearing enables monitoring of the amount of lubricant inside the bearing in a simplified manner compared to conventional ways.
Note that such a bearing is different from conventional bearings by the presence of the compressor unit which is connected to the pressure compensation hole and which is able to selectively apply a pressure to push, i.e. to blow a compressed medium into the bearing.
Such a ventilation device can be used to indirectly determine and monitor the amount of lubricant inside the bearing. Note, however, that such a ventilation device can also be used to reliably ensure that the pressure compensation hole remains substantially unobstructed. This is due to the fact that by blowing the compressed medium through the pressure compensation hole, a consequence is that any dried lubricant which is present in the pressure compensation hole is blown into the bearing. As a consequence thereof the pressure compensation hole is freed of used lubricant after applying the pressure.
Note as well that in practice, however, it seems to be advantageous to separate the process of ensuring that the pressure compensation hole remains unobstructed and to deliberately blow in air into the bearing in order to indirectly monitor and determine the amount of lubricant inside the bearing.
In an advantageous embodiment, the bearing further comprises a lubricant drain hole for enabling lubricant to exit the bearing in a controlled manner.
This is advantageous in order to avoid that leakage of lubricant occurs at random positions, which might be needed to be identified first, and which then might be difficult to access.
In other words, this is advantageous in order to avoid overfilling and subsequent high risk of leakage.
It is also advantageous that the bearing comprises means which enable to selectively shut the lubricant drain hole. One non-limiting example of such means is a drain hole valve for having the option to selectively shut, i.e. to close the lubricant drain hole.
The embodiment can advantageously be applied to the main bearing of a wind turbine, as these bearings are particularly prone to increased leakage rates and refill issues. If the wind turbine comprises more than one main bearing, the present invention can be applied to some or all of these main bearings.
Note, however, that embodiments of the present invention are in principle applicable to any bearing of a wind turbine. It is even applicable to any bearing, i.e. also to bearings in other applications than wind turbines.
In one embodiment of the invention, the compressor unit is connected with the pressure compensation hole via a flexible hose and/or a stiff pipe.
Additionally, it is also preferred that the ventilation device further comprises another valve, in particular a two-way valve, which is arranged such that the valve can be closed during cleaning of the pressure compensation hole—such that a maximum pressure can be applied to the at least partially obstructed pressure compensation hole—and that the valve can be opened during an inactive state of the compressor unit such that a maximum pressure compensation between the sealed bearing and the ambient can be achieved.
The provision of such a valve has the effect that the compressed medium which is blown through the compressor compensation hole is used and exploited optimally.
It is furthermore advantageous, that the ventilation device comprises a pressure transducer for monitoring the pressure inside the bearing.
In practice, even a plurality of pressure transducers being distributed around the bearing may be used in order to even more reliably determine and monitor the pressure inside the bearing. A reliable but simple method to determine the actual absolute pressure inside the bearing is fundamental for carrying out the inventive method.
Finally, embodiments of the invention is also directed towards a wind turbine for generating electricity, wherein the main bearing of the wind turbine supporting the rotor of the wind turbine comprises a bearing such as described above.
Some of the embodiments will be described in detail, with references to the following Figures, wherein like designations denote like members, wherein:
The illustration in the drawings is schematically. Note that similar features and elements may be denoted by the same reference signs.
The inner bearing ring 11 comprises a pressure compensation hole 21. The purpose of the pressure compensation hole 21 is to enable a pressure compensation between the pressure inside the bearing 10 and the ambient. The pressure compensation hole 21 is directly connected with a connection means 22, e.g. a flexible hose. At the opposite end of the connection means 22, i.e. opposite to the pressure compensation hole 21, a compressor unit 23 is arranged. The compressor unit 23 is a small air compressor for providing a pulse of compressed air during a pulse length of a few seconds. The compressor unit 23 is configured by a controller which activates and deactivates the compressor.
The ventilation device 20 furthermore comprises a pressure transducer 25. The pressure transducer 25 is arranged at the inner bearing ring 11 and is able to continuously monitor the pressure inside the bearing 10. The pressure transducer 25 may in particular be able to transmit the determined pressure values in a wireless manner to a controller unit where these pressure values are further processed.
Furthermore, the inner bearing ring 11 comprises a pressure compensation hole 21. This pressure compensation hole 21 enables a pressure equalization between the volume inside the bearing and the ambient. The pressure compensation hole 21 is directly connected via connection means 22 with a compressor unit 23. The compressor unit 23 has the objective to deliberately and selectively inject a compressed medium through the pressure compensation hole 21 into the bearing 10. By this, the compressor unit 23 has, on the one hand, the possibility to blow used and dried lubricant being present in the pressure compensation hole 21 into the bearing, and, on the other hand, it provides means to deliberately create overpressure inside the bearing which can be used for monitoring the amount of lubricant inside the bearing.
Note that the bearing 10 of
Finally,
In the example as illustrated in
Although the invention has been illustrated and described in greater detail with reference to the preferred exemplary embodiment, the invention is not limited to the examples disclosed, and further variations can be inferred by a person skilled in the art, without departing from the scope of protection of the invention.
For the sake of clarity, it is to be understood that the use of “a” or “an” throughout this application does not exclude a plurality, and “comprising” does not exclude other steps or elements.
Number | Date | Country | Kind |
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15198477 | Dec 2015 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/080018 | 12/7/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/097809 | 6/15/2017 | WO | A |
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20180266488 A1 | Sep 2018 | US |