The present invention relates to a positive displacement machine such as a compressor, expander, pump or the like, for displacing a gaseous or liquid medium.
Such positive displacement machines which contain an element with an inlet and an outlet for the medium and with at least two cooperating driven moving parts are already known, whereby the mutual movement of the moving parts displaces the medium from the inlet to the outlet, whereby the element is provided with a kinematic coupling between the at least two cooperating parts for the mutual synchronisation of the movements of these parts.
An example of such positive displacement machine is a screw compressor or a screw expander whereby the aforementioned element is provided with two helical cooperating rotors which partly engage their screws in each other to compress or expand gas between the screws by their mutual movement.
Such element of a screw compressor or screw expander is always provided with one single drive in the form of a rotative motor which drives one of both helical rotors through the agency of a robust gear transmission.
The other rotor is then driven via the first rotor and through the agency of a torque transfer transmission between both rotors in the form of two so-called synchronisation gears which transmit the torque of the first rotor in whole to the second rotor with a fixed transmission ratio.
Such screw compressor is known for example from BE2015/5250.
The torque transfer transmission between both rotors is not only to transmit the torque but also to prevent the rotors from touching each other during rotation, which in the case of an oil-free screw compressor would otherwise lead to premature wear or damage due to the lack of oil lubrication.
The power required to displace the medium at a certain flow rate and at a certain pressure is thus supplied entirely by the single drive and transmitted entirely via the gear transmission to one of both rotors and via this rotor is partially transmitted to the second rotor.
A disadvantage is that the drive must have sufficient power to be able to provide this full power, which in the event of large powers may inevitably lead to choosing a large and bulky motor, for which there is not always sufficient space available at the user.
Additionally, the gear transmission between the single drive and one of the rotors and the rotor driven by the gear transmission must be designed to be able to cope with this supplied power and the related axial and radial forces and torques and furthermore the bearings in which the gearwheels of the gear transmission and of the transmission and the bearings in which the rotors are mounted with bearings must be calculated for this, which in its entirety can lead to relatively heavy, sizable and expensive solutions.
The invention is not limited to screw compressors or screw expanders, but applies to many other types of positive displacement periodic machines.
The purpose of the present invention is to provide a solution to one or more of the aforementioned and other disadvantages.
To this end, the invention relates to a positive displacement machine such as a compressor, expander, pump or the like, for displacing a gaseous or liquid medium, the machine containing an element with an inlet and an outlet for the medium and at least two cooperating driven moving parts, whereby the medium is displaced from the inlet to the outlet by the mutual periodic movement of the moving parts, characterised in that each of the at least two driven cooperating moving parts is provided with its own individual drive and that the element is provided with a kinematic synchronisation coupling between the at least two cooperating moving parts for the mutual kinematic synchronisation of their movements.
In this way, the power required to displace the medium with a given flow rate at a given pressure with the positive displacement machine is supplied by two separate individual drives, each with a smaller power than the total power required.
Due to the smaller power, smaller drives with a considerably smaller mass can be chosen, which can also be driven at higher speeds in a favourable manner.
As, according to the invention, the required power does not entirely need to be transmitted via the gear transmission and one of the at least two drives, according to the invention these components can also be made lighter than in the case of a single drive, and the bearings of these components will also be subjected to less big forces and thus have to meet lower requirements, which in turn can lead to cheaper bearings and thus to a lower cost of the positive displacement machine.
By lowering the masses of the moving parts, said parts can be driven at a higher speed such that the gear transmission can be reduced or preferably even completely left out by directly coupling the individual drives to the cooperating moving parts.
In this way, savings are realised in terms of the gear transmission and of the bearings of this transmission, resulting in fewer losses and thus a better efficiency of the positive displacement machine and a more compact and cheaper machine.
The kinematic synchronisation coupling between the moving parts must ensure that the moving parts never collide with each other, even if the individual drives drive unevenly, and in other words keeps the moving parts apart in a mechanically forced manner.
Also when the drive of the moving parts by the individual drives is not fully synchronised due to the inevitable imperfections in the drive and its synchronisation control, the kinematic synchronisation coupling will still ensure an imposed forced synchronisation.
Optimally balanced synchronous driving by means of the individual drives allows the kinematic synchronous coupling between the cooperating moving parts not to be loaded, or only to a very limited extent, as then they only need to accommodate the difference between the individual powers supplied by the individual drives to the moving parts.
This means the kinematic synchronisation coupling and its bearings, if any, can be designed lighter and in other words cheaper and smaller than the kinematic coupling of the known positive displacement machines with one single drive.
Preferably, the positive displacement machine according to the invention is also provided with a synchronisation controller to mutually synchronise the individual drives, i.e. to ensure that the individual drives are controlled in such a way that the cooperating moving parts do not come into contact with each other, at least theoretically cannot come into contact with each other.
However, in practice it has not yet been possible to develop a perfectly marketable controller that can react sufficiently quickly and accurately in all circumstances to ensure that the cooperating moving parts would not collide with each other if there was no synchronisation coupling present.
However, the kinematic synchronisation coupling does ensure that the errors of the synchronisation controller are compensated.
The synchronisation controller is a soft controller as it were, particularly a software-based controller, whereas the kinematic synchronisation coupling is a hard controller.
The invention particularly applies to positive displacement machines, the cooperating moving parts of the element of which are rotative parts and/or the individual drives are rotative drives, as in the case of a screw compressor or a screw expander with an element with two helical cooperating driven rotors which partly engage with their screws to compress or expand gas between the screws by their mutual movement.
In that case it is preferable according to the invention that the cooperating rotative parts are provided with a shaft and the individual rotative drives are provided with an output drive shaft with which they are directly coupled to the shaft of a relevant driven part.
In this way, savings are realised in terms of a transmission between the individual drives and the cooperating moving parts. The advantages of this are fewer moving parts, smaller size and less heavy.
Rotative is also understood to mean oscillating rotative or orbiting rotative as in the case of a spiral compressor, for example.
According to a simple realisation, the kinematic synchronisation coupling contains a gear transmission between the at least two cooperating moving parts of the element.
According to a preferred embodiment, the positive displacement machine is an oil-free screw compressor or an oil-free screw expander or tooth compressor. In this type of positive displacement machines, the synchronisation between the cooperating rotating parts is extremely important, as they may not make any contact due to the lack of a lubricating oil film and the very tight play between the engaging rotors which is necessary to minimise the leaks of the compressed medium between the rotors as much as possible.
According to a practical realisation of the invention the individual drives are, more particularly, rotative drives with a variable adjustable speed and the synchronisation controller contains a primary control algorithm for controlling the speed of one of the at least two individual rotative drives, referred to as the master drive here, as a function of a set primary control criterion, for example for controlling a desired pressure or a desired flow rate of the medium displaced by the machine.
Preferably the synchronisation controller contains a secondary control algorithm for controlling the speed of the other of the at least two individual rotative drives, referred to as the slave drive here, and this in such a way that the speeds of the master drive and the slave drive are mutually synchronised, e.g. in such a way that the ratio between the speed of the master drive and the speed of the slave drive is practically constant, preferably with a maximum deviation of less than 5%, even more preferably less than 2% and most preferably less than 1%.
The invention also relates to a method for displacing a liquid or gaseous medium by means of a positive displacement machine with an element with at least two cooperating driven moving parts which by their mutual periodic movement can displace the medium, whereby the method comprises the following steps:
Preferably the method also applies the step of synchronously driving the individual drives and preferably comprises the following steps:
With the intention of better showing the characteristics of the invention, hereafter, by way of an example without any limiting nature, a preferred embodiment is described of a positive displacement periodic machine according to the invention and of a method thereby applied for displacing a liquid or gaseous medium, with reference to the accompanying drawings, wherein:
In this case, by way of an example, the known positive displacement machine 1 shown in
In this case the machine 1 contains one single and sole drive 1 in the form of an electric motor 2 and an element 3 with two cooperating moving parts 4, respectively a first and a second moving part 4a and 4b, in the form of two helical rotors which partially engage with their screws 5 and which have been rotatably mounted in a housing 3′ of the element 3 with therein two overlapping cylindrical compression chambers 6 in which the cooperating moving parts 4 have been mounted closely fitting.
The cooperating moving parts 4 are provided with a shaft 7, respectively 7a and 7b, which are mounted on bearings by means of radial and axial bearings 8 in the housing 3′ to secure the moving parts 4 in this case axially and radially.
The machine 1 contains a torque transfer transmission 9 with an input shaft 10 which is coupled directly or by means of a coupling 11 to the aforementioned single drive 2 and an output shaft 12 which may or may not be connected by means of a coupling 13 to the shaft 7a of the first moving part 4a.
The input shaft 10 and the output shaft 12 are mounted in the housing 5 by means of extra bearings 14.
In this case the transmission is a gear transmission with two engaging gearwheels 15, respectively a floating gearwheel 15b on the input shaft 10 and a driven gearwheel 15a on the output shaft 12, which is connected to the first moving part 4a.
In operation, the machine 1 is driven by means of the drive 2 which drives the first moving part 4a via the transmission 9.
The second moving part 4b is driven via a second torque transfer transmission 16 by the shaft 7a of the first moving part 4a, for which purpose a floating gearwheel 17a is mounted on the shaft 7a which engages with a driven gearwheel 17b on shaft 7b of the second moving part 4b.
Thanks to the drive both moving parts 4a and 4b are synchronously driven, for example at the same speed with the same number of revolutions, such that a gaseous medium is sucked in via an inlet 18 in the housing 3 and compressed between the screws 5 and is displaced to an outlet 19 in the housing to be supplied at a higher pressure to a pneumatic consumer.
The power required to supply the gaseous medium at a given pressure to the outlet 19 and a given flow rate to the consumer passes entirely over the transmission 9 and a significant part of this power passes over the transmission 16 and the moving parts that must be designed to cope with it. The bearings also have to be able to cope with it.
Specific to the invention is that, in this case, each of the two cooperating moving parts are provided with their own individual drive 20, 20a and 20b respectively, each of which in this case is directly coupled by means of a coupling 21, 21a and 21b respectively, to a respective shaft 7a and 7b of the cooperating moving parts 4a and 4b and that the element 3 is provided with a kinematic synchronisation coupling 22 between the at least two cooperating moving parts 4a and 4b for the mutual kinematic synchronisation of their movements.
The couplings 21a and 21b do not necessarily have to be separate couplings, but can also be a direct mechanical connection whereby the shafts of the drives 20a and 20b are one with the shafts 7a and 7b.
The shafts 7a and 7b are mounted in the housing 3′ by means of bearings 8.
In the example the synchronisation coupling 22 is formed by two engaging gearwheels 23, a gearwheel 23a on the shaft 7a of the first moving part 4a and a gearwheel 23b on the shaft 7b of the second moving part 4b respectively.
The synchronisation coupling 22 has a fixed transmission ratio between the gearwheels 23a and 23b.
In this case the drives 20a and 20b are located at one axial end of the element 3, while the synchronisation coupling 22 is located at the other axial end of the element 3. However, it is not excluded that both drives 20a and 20b are located on the same axial end of the element 3 as the synchronisation coupling 22 or that one drive 20a is located at the same axial end as the synchronisation coupling 22 and the other drive 20b is located at the other end.
Analogue to
The drives 20a and 20b are drives with a variable adjustable speed n and the positive displacement machine is provided with a synchronisation controller 24 which is connected to the drives 20a and 20b for the synchronous control of the speeds na and nb of the cooperating moving parts 4a and 4b with a fixed ratio between the speeds na and nb, at least apart from the possible errors of the controller.
To this end, the element 3 is provided with means 25, respectively 25a and 25b, to determine the speed na and nb of the individual drives 20a and 20b, said means 25 being connected with the aforementioned synchronisation controller 24 for the feedback of the speeds.
Furthermore, the positive displacement machine 1 is provided with means 26 to determine the pressure p at the outlet 19 of the element 3 and/or the flow rate of the displaced medium.
Preferably the synchronisation controller 24 contains a primary control algorithm for controlling, for example, the speed na of one of the individual drives 20a, referred to as the master drive here, and this as a function of a set primary control criterion which is, for example, a desired pressure p or a desired flow rate as is already traditionally applied in positive displacement machines.
A secondary control algorithm of the synchronisation controller will then control the speed nb of the other individual drive 20b, referred to as the slave drive here, and this in such a way that the speeds na and nb of the master drive and of the slave drive are mutually synchronised.
The secondary control algorithm is for example such that the ratio na/nb between the speed na of the master drive 20a and the speed nb of the slave drive 20b is practically constant and equal or practically equal to a set value (na/nb) which is equal to the fixed transmission ratio of the kinematic synchronisation coupling 22, with a maximum deviation which is preferably less than 5%, more preferably less than 2% and most preferably less than 1%.
The method for using the positive displacement machine 1 according to the invention is simple and as follows.
The speed of the individual drive is controlled by the primary control algorithm such that a set pressure p at the outlet of 19 of the element 3 or a set flow rate is maintained.
Further, the secondary control algorithm ensures the second individual drive 20b is driven synchronously with the first individual drive 20a, i.e. making sure that the ratio between the speeds na and nb always remains equal to the set value (na/nb) set which is equal to the transmission ratio of the kinematic synchronisation coupling 22. In other words, the speed nb of the slave drive 20b follows the variations of the speed na of the master drive 20a.
With a theoretically perfect controller 24, no torque and therefore no power will be transmitted through the synchronisation coupling 22.
However, in case of a deviation of the synchronisation controller 24, the speed nb for example will lag slightly behind the speed na with a certain deviation in relation to the set speed ratio (na/nb) set.
Without the kinematic synchronisation coupling 22 this would mean that the cooperating moving parts 4a and 4b would interfere against each other, which must be absolutely avoided.
However, the presence of the kinematic synchronisation coupling 22 avoids this forcefully and the moving part 4a with the greatest speed will help drive the moving part 4b with a lower speed via the kinematic synchronisation coupling 22 which will then have to absorb the power difference which is, however, limited and all the more limited such that the control of the speed by the synchronisation controller is more accurate.
It is clear that thanks to this the kinematic synchronisation coupling 22 can be made relatively light.
It is also clear that by applying the invention the relatively robust torque transfer transmissions 9 of the known positive displacement machine of
For the primary control other criteria can be applied than a set pressure or flow rate such as a power control or the like.
The secondary control can also be based on other control criteria such as minimising the power transmitted via the kinematic synchronisation coupling 22.
It is also clear that the positive displacement machine does not necessarily have to be a rotative machine but also applies to, for example, machines with periodically linear moving parts between which a gaseous or liquid medium is displaced and which are each provided with their own individual drive and the frequency of the drives of which needs to be synchronised to avoid collisions.
The present invention is by no means limited to the embodiment described as an example and shown in the drawing, but a positive displacement periodic machine according to the invention and a method applied thereby for displacing a liquid or gaseous medium can be realised in all kinds of ways and forms without departing from the scope of the invention.
Number | Date | Country | Kind |
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2018/5894 | Dec 2018 | BE | national |
2018/5896 | Dec 2018 | BE | national |
2019/5922 | Dec 2019 | BE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2019/060919 | 12/17/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/128830 | 6/25/2020 | WO | A |
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5674063 | Ozaki | Oct 1997 | A |
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Number | Date | Country | |
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20210396229 A1 | Dec 2021 | US |