AT524547B1 - Reciprocating compressor and method of operating a reciprocating compressor - Google Patents

Abstract

In order to avoid overlubrication of the cylinders (2) in a piston compressor (1) and to reduce the amount of lubricant to a level required for operation, a lubrication system with a lubrication system control unit (14) is provided according to the invention, in which at least one lubricant sensor (15) is provided for detecting a lubricating film measured variable (S) representative of a lubricating film thickness of a lubricating film (11) on the cylinder running surface of the cylinder (2), the lubricating system control unit (14) being designed to control the lubricating system during operation of the piston compressor (1) to operate at least once in a predetermined calibration operating mode and to determine a lubricating film condition value (SZ) on the basis of the lubricating film measured variable (S) recorded while the calibration operating mode is being carried out, and that the lubrication system control unit (14) is designed to do so after the end of the calibration operating mode during operation of the piston compressor (1) the to control the quantity of lubricant to be introduced as a function of the determined lubricating film condition value (SZ).

Description

description

RECIPROCATING COMPRESSOR AND METHOD OF OPERATING A RECIPROCATING COMPRESSOR

The invention relates to a lubricating system for a reciprocating compressor for introducing a lubricant onto a cylinder running surface of a cylinder of the reciprocating compressor, in which a piston can be moved back and forth, with a lubricating system control unit for controlling an amount of lubricant to be introduced being provided. The invention further relates to a piston compressor with a lubrication system and a method for operating a piston compressor with at least one cylinder, in which a piston is moved back and forth, with a lubricant being supplied to a cylinder running surface of the at least one cylinder by means of a lubrication system and with a quantity of lubricant of the supplied lubricant is controlled by a lubrication system control unit.

In piston machines, especially in lubricated piston compressors, the reliable lubrication of the cylinder is of great importance for reliable operation. As a rule, each cylinder has one or more lubrication points through which a lubricant can be introduced into the cylinder. The lubrication points are usually supplied with lubricant from a central lubrication system. Dosing the lubricant into the cylinders as precisely as possible is crucial for reliable operation. Too little lubricant leads to increased wear on the moving components of the compressor, in particular on the piston rings or packing rings of sealing packings with which the piston rod is sealed. Increased wear leads to a reduced service life of these components and thus to reduced availability of the compressor. Conversely, too much lubricant usually leads to reduced life of components such as compressor valves due to oil sticking effect, as well as reduced life of downstream equipment such as catalytic converters. In addition, high amounts of lubricant naturally lead to increased operating costs due to lubricant consumption, as well as higher capital costs because additional equipment such as special separators is required to remove excess lubricant from the compressed process stream.

Known lubrication systems are usually based on a predetermined amount of lubricant for the respective piston engine. These specified amounts of lubricant are typically provided by the compressor manufacturers depending on the compressor type, size and process parameters and are based on empirical data or simplified calculation models. Due to uncertainties in these calculation models and to cover all types of construction and operating conditions of the compressors, safety factors are usually provided that are chosen conservatively, so that more lubricant is usually supplied than is necessary. Such "over-lubrication" of the cylinders during operation is of course disadvantageous for the operator of a piston compressor for the reasons mentioned above and is therefore undesirable.

It is therefore an object of the invention to provide a piston compressor and a method for operating a piston compressor with which overlubrication of the cylinders can be avoided and the amount of lubricant can be reduced to a level required for operation.

The object is achieved with the lubricating system mentioned at the outset in that at least one lubricant sensor is provided for detecting a lubricating film measured variable that is representative of a lubricating film thickness of a lubricating film on the cylinder running surface of the cylinder, in that the lubricating system control unit controls the lubricating system during operation of the piston compressor at least operates once in a predetermined calibration mode, determines a lubricant film condition value based on the lubricant film measurement variable detected while the calibration mode is being carried out, and in operation after the end of the calibration mode

of the piston compressor controls the quantity of lubricant to be introduced depending on the determined value of the condition of the lubricating film. This creates a lubrication system that automatically detects the condition of the lubricating film on the cylinder liner by measuring the thickness of the lubricating film and evaluating the measurement result, and based on this automatically provides a suitable quantity of lubricant. As a result, the amount of lubricant required can be significantly reduced compared to conventional lubrication systems, so that the cylinders are not over-lubricated.

The lubricant sensor is preferably an ultrasonic sensor, with a temporal resolution of the lubricant sensor preferably being 0.01° to 5° crank angle. This makes it possible to easily record the measured variable of the lubricating film without having to have direct access to the cylinder running surface. For example, an ultrasonic sensor can easily be placed on the outside of an existing cylinder.

Preferably, the lubrication system control unit uses a sensor value of the measured lubricant film variable to determine the lubricant film condition value, which is detected during a piston stroke of the piston at a time when a piston ring of the piston is in the sensor area of the lubricant sensor, preferably one during the Piston stroke recorded minimum value of the lubricating film measurement variable. This allows conclusions to be drawn about the current thickness of the lubricating film in the area of a piston ring and, based on this, the required amount of lubricant can be determined.

Preferably, the lubrication system is designed for intermittent introduction of the lubricant into the cylinder, preferably as a pump-to-point system, as a divider block system or as a common rail system, and the lubrication system control unit controls the amount of lubricant by a Changing a frequency and/or an injection amount of each injection of the intermittent injection of the lubricant. This means that proven lubrication systems can be used and calibrated accordingly.

Preferably, the lubrication system controller repeats the calibration mode of operation at a specified cycle to update the lube condition value and adjust the amount of lubricant to the updated lube condition value. As a result, changes occurring during operation that may require a greater or lesser quantity of lubricant, for example wear on the piston rings, can be taken into account.

A duration of the calibration operating mode is preferably at least ten, preferably at least one hundred, particularly preferably at least one thousand crankshaft revolutions of the piston compressor or an equivalent time. This gives sufficient time to set and evaluate different states of the lubricating film.

Preferably, in the calibration operating mode, at least two consecutive time ranges with different amounts of lubricant are defined and the lubrication system control unit determines a maximum value and a minimum value in a time profile of the measured lubricant film variable recorded during the at least two time ranges and uses this to determine the lubricant film state value for controlling the amount of lubricant. Particularly preferably, a first time range with a specified duration and a subsequent second time range with a specified duration are defined and the quantity of lubricant introduced during the first time range is defined in such a way that a completely wetted lubricating film is formed on the cylinder running surface and the amount of lubricant introduced during the second time range The quantity of lubricant is determined in such a way that dry running occurs on the cylinder surface. The duration of the first time range is preferably at least five crankshaft revolutions and the quantity of lubricant introduced during the first time range is preferably 90-200% of a quantity of lubricant specified by the compressor manufacturer. The duration of the second time period is preferably at least five crankshaft revolutions and the amount of lubricant introduced during the second time period is preferably 0% of the amount of lubricant specified by the compressor manufacturer. In this way, various lubricating film conditions are simulated and used to determine a representative, generally applicable

used to determine the lubricating film condition value.

It is advantageous if the lubrication system control unit determines a differential value between the determined maximum value and the determined minimum value, determines a lubricating film limit value from the maximum value and the determined difference value and uses the lubricating film limit value as the lubricating film state value. The lubrication system control unit then controls the lubrication system for introducing the lubricant during operation of the piston compressor after the end of the calibration operating mode if the measured lubricant film variable is in a lubrication system activation range between the minimum value and the lubricant film limit value. On the one hand, this creates a differential evaluation method that is essentially independent of the recorded absolute values of the recorded lubricant film measurement variable, and a simple indicator for activating the introduction of lubricant is provided.

A lubricant quantity detection unit is preferably also provided in the lubrication system for detecting a quantity of lubricant supplied to the lubrication point, and the lubrication system control unit compares the lubricant film measured variable obtained from the lubricant film sensor and the lubricant quantity obtained from the lubricant quantity detection unit in order to check the two values for consistency and/or to detect a leak in the lubrication system. This allows the function of the lubricant sensor to be checked and leaks in the lubricant lines to be detected. Based on this, certain actions, such as switching off the compressor or changing the lubrication to conventional U-overlubrication, can be carried out, which can increase operational reliability.

The invention is also achieved with a method in that at least one lubricant sensor is used to detect a lubricating film measurement variable that is representative of a lubricating film thickness of a lubricating film on the cylinder running surface of the cylinder, that the lubricating system is monitored by the lubricating system control unit at least once during operation of the piston compressor is operated in a predetermined calibration operating mode, with a lubricant film condition value being determined on the basis of the lubricant film measured variable recorded during the implementation of the calibration operating mode, and that the lubrication system control unit controls the lubricant quantity to be introduced in the operation of the piston compressor after the end of the calibration operating mode, depending on the lubricant film condition value determined.

The present invention is explained in more detail below with reference to FIGS. 1 to 4, which show advantageous configurations of the invention by way of example, schematically and not restrictively. while showing

[0016] FIG. 1 shows a section through a cylinder of a piston compressor, [0017] FIG.

[0018] FIG. 3a shows a diagram with a time profile of the detected lubricating film measured variable over the compressor revolutions of the piston compressor,

[0019] FIG. 3b shows a diagram with a percentage quantity of lubricant over the compressor revolutions of the piston compressor,

[0020] FIG. 4 shows a diagram with a measured lubricating film variable plotted against the crank angle of the piston compressor.

In Figure 1 is a simplified sectional view through a cylinder 2 of a piston compressor 1 is shown. A piston 3 is arranged in a known manner in the cylinder 2 and can be moved back and forth in the cylinder between a top dead center OT and a bottom dead center UT. The piston 3 can be driven in a known manner by a crankshaft (not shown) via a connecting rod (not shown), a crosshead (not shown) and a piston rod 4 . Of course, other designs of the piston compressor 1 would also be possible, for example a direct drive of the piston 3 by a connecting rod

without crosshead and piston rod 4. In the example shown, a cylinder sleeve 5, a so-called liner, is arranged in the cylinder 2, on the inner peripheral surface of which a cylinder running surface for the piston 3 is formed.

In principle, however, an embodiment without a cylinder liner 5 is also possible, in which the cylinder running surface is provided directly on the inner peripheral surface of the cylinder 2 . A piston compressor 1 can, of course, have a plurality of cylinders 2, in each of which a piston 3 can be moved back and forth, it being possible for the plurality of pistons 3 to be driven by a common crankshaft. One or more piston rings 6 can be provided on the piston 3 and are arranged in suitable circumferential grooves on the circumferential surface of the piston 3 . Within the scope of the invention, a piston ring 6 is generally to be understood as meaning piston rings with different functions. For example, a piston ring 6 can be designed as a sealing ring, as a support ring or as a scraper ring. A sealing ring is designed, for example, to seal against a differential pressure, while a support ring usually has no sealing effect and is designed to support the load of the piston 3 on the cylinder liner. A scraper ring, in turn, is designed to scrape the lubricating film from the cylinder running surface.

Of course, not all designs must be provided on a piston 3, but it could also be provided, for example, only a piston ring 6, for example in the form of a sealing ring. In the example shown, three piston rings 6a, 6b, 6c are provided, the first and third piston rings 6a, 6c being designed as sealing rings and the second piston ring 6b being designed as a support ring. However, more or fewer piston rings 6 could also be provided, e.g. an oil scraper ring. It can be seen that the support ring 6b has a greater width (in the axial direction) than the sealing rings 6a, 6c, which is usually the case. In addition, the groove in the piston 3, in which the support ring 6b is arranged, is designed in such a way that the support ring 6b rests directly on the bottom of the groove. In contrast to the sealing rings 6a, 6c, the support ring 6b is thus essentially immovable in the radial direction in order to be able to support the load of the piston 3 better. The sealing rings 6a, 6c, on the other hand, can be moved radially in the respective grooves in order to be able to create a better seal. In general, a piston ring 6 can, of course, also have a certain overhang over the piston 3 in the radial direction, which is not shown in FIG. 1 for the sake of simplicity.

In the cylinder 2, a compression chamber 7 delimited by the piston 3 is formed in a known manner, on which a suction valve 8 and a pressure valve 9 are arranged. During an expansion stroke, the piston 3 is moved from top dead center OT to bottom dead center UT, and during a compression stroke, the piston 3 is moved from bottom dead center UT to top dead center OT. During the expansion stroke, a gaseous medium to be compressed, for example air or a process gas, can be sucked into the compression chamber 7 via the suction valve 8 . During the compression stroke, the medium in the compression chamber 7 is compressed and discharged from the compression chamber 7 via the pressure valve 9 . The suction valve 8 and the pressure valve 9 are only indicated in FIG. 1 as schematic circuit symbols and can be designed in different ways.

It can also be provided on the cylinder several suction valves 8 and pressure valves 9. The suction valve 8 and the pressure valve 9 do not necessarily have to be arranged on the end face of the cylinder 2, but could also be provided on the peripheral surface of the cylinder 2 in the compression space 7, for example. For example, the suction valve 8 and the pressure valve 9 can be designed as known automatic ring valves, it also being possible for an unloader to be provided to keep the valves open. The unloader can be controlled by a suitable compressor control unit 10 to regulate the capacity of the compressor 1 .

The piston compressor 1 also has a lubricating system for lubricating the at least one cylinder 2 . The lubricant forms a lubricating film 11 in the cylinder 2 to reduce the friction between the relative to each other

to minimize moving components, in particular between the piston 3 or piston rings 6 and the cylinder surface. In order to enable the lubricant to be distributed as evenly as possible in the cylinder 2, several lubricating points 12 can of course also be provided, which can be arranged spaced apart on the cylinder 2, for example in the axial direction and/or in the circumferential direction, as in Figure 1 by the lubricating points 12a , 12b is indicated. Depending on the structural design of a piston ring 2, it can be advantageous if the lubricant is introduced via the lubricating point 12 in the compression stroke and/or in the expansion stroke, for example before the respective piston ring 2 reaches the lubricating point 12, while the piston ring 2 is in the area of the lubricating point 12 or possibly also after the respective piston ring 2 has passed the lubricating point 12 . The point in time at which it is introduced essentially depends on the lubrication system used.

Various lubrication systems are known in the prior art, including the so-called “divider block” systems, “pump-to-point” systems and “common rail” systems. In a “divider block” system, a central delivery unit for delivering the lubricant and what is known as a “divider block” for distributing the lubricant to the lubrication points 12 of the cylinders 2 are provided. The quantity of lubricant conveyed by the central conveying unit is supplied to a so-called “divider block”, divided up in this and conveyed to the individual lubrication points 12. The lubricant is generally introduced into the cylinder 2 intermittently via individual injections. The amount of lubricant to be introduced is controlled by appropriate control of the central delivery unit. If the central delivery unit is designed as a piston pump, for example, the delivery quantity can be controlled via the speed and/or possibly via the piston stroke. A change in the amount of lubricant during operation of the compressor 1 can be done, for example, by changing the frequency of the intermittent individual injections of the lubricant, for example by changing the pump speed. Due to the central delivery unit, however, the amount of lubricant can only be changed in a constant ratio for all available lubrication points 12 . Different quantities of lubricant for different lubrication points 12 or different cylinders 2 are not usually possible here.

In a "pump-to-point" system, each lubrication point 12 or each cylinder 2 is assigned its own delivery unit, e.g. a piston pump. Depending on the structural design of the delivery unit, for example the stroke or displacement of the piston pump, a corresponding quantity of lubricant is delivered to the assigned lubrication point 12, again as a rule intermittently over individual injections. As a rule, the delivery units, in particular the piston pumps, are driven via a common camshaft. A change in the amount of lubricant during operation of the compressor 1 can be done, for example, by changing the frequency of the individual injections of the lubricant by adjusting the speed of the camshaft. A change in the quantity of lubricant usually only takes place in a constant ratio for all lubrication points 12. In some "pump-to-point" systems, however, the delivery quantities can also be changed separately, for example by an adjustable stroke of the piston pumps. As a result, the amount of lubricant at each lubrication point 12 or for each cylinder 2 can be adjusted individually. Suitable adjustment devices can be provided on the conveyor units, for example, to change the amount of lubricant. The adjusting device can be designed for manual adjustment of the stroke of a piston pump, for example, or a suitable actuator can be provided for adjusting the stroke, so that the quantity of lubricant introduced can be changed for each injection.

In addition, there are also so-called "common rail" systems, in which the lubricant is conveyed by a high-pressure pump into a pressure accumulator and can be supplied individually from the pressure accumulator by means of electrically controllable injectors via pressure lines to each lubrication point 12 or each cylinder 2. In comparison to the previously mentioned systems, such systems offer the greatest degree of freedom in controlling the introduction of the lubricant. In particular, the amount of lubricant can be changed not only by changing the

The frequency of the intermittent injection can be changed, but the amount of lubricant introduced per injection can also be controlled very precisely and variably. In addition, the time of introduction at each lubrication point 12 or at each cylinder 2 can be adjusted individually and essentially independently of the operation of the high-pressure pump (as long as there is sufficient pressure in the pressure accumulator). This makes it possible, for example, for a piston compressor 1 whose piston 3 has a plurality of piston rings 6 to carry out multiple injections within a piston stroke, so that each piston ring 6 can be supplied with a specific quantity of lubricant.

In all lubrication systems, the control of the lubricant injection, for example the time of an injection and/or the amount of lubricant per injection and/or the frequency of the injections, is usually carried out via a suitable lubrication system control unit 14. The lubrication system control unit 14 can be used as a separate hardware and /or software or can be integrated, for example, in a higher-level control unit such as the compressor control unit 10 . In FIG. 1, a “common rail” system is shown merely as an example, with an electrically controllable injector 13 being provided for each lubrication point 12, which injector can be designed, for example, as an electromagnetic injector or as a piezo injector. The injectors are connected to a central lubrication system control unit 14 by any suitable communication link, such as electrical wiring. As mentioned above, a pressure accumulator and a high-pressure pump are also provided, but these are not shown in FIG. 1 for the sake of simplicity. The high-pressure pump is preferably also controlled by the lubrication system control unit 14 . The lubrication system control unit 14 can, for example, communicate with a compressor control unit 10 in order to obtain operating parameters BP of the piston compressor 1 that are relevant for the control of the lubrication system. Such operating parameters BP can, for example, contain current data about the operating state of the compressor 1, for example a load signal L, a speed signal N, a crank angle signal °KW, lubricant temperature T, etc. The lubrication system control unit 14 can take the operating parameters BP into account when controlling the lubrication system.

As mentioned at the outset, the amount of lubricant has hitherto been controlled as a rule on the basis of manufacturer specifications, which often led to over-lubrication, ie to the introduction of an excessive amount of lubricant than necessary. In order to avoid this, an automatic calibration of the lubrication system is provided according to the present invention, as a result of which the amount of lubricant can be adapted to the actual requirement. For this purpose, at least one lubricant sensor 15 is provided in the lubricating system for detecting a lubricating film measured variable S representative of a lubricating film thickness of the lubricating film 11 on the cylinder running surface of the cylinder 2 . The measured lubricating film variable S is essentially a measure of the lubricating film thickness of the lubricating film 11 on the cylinder running surface in a sensor area of the lubricant sensor 15. The lubricant sensor 15 is connected to the lubricant control unit 14 via a suitable communication link in order to transmit the measured lubricating film variable S to the lubricant To transmit control unit 14, for example via suitable electrical measuring lines. An acoustic sensor, in particular an ultrasonic sensor, is preferably provided as the lubricant sensor 15 . The lubricant sensor 15 can be arranged at a suitable location on the outside of the cylinder 2, for example.

The lubricant sensor 15 is preferably arranged in the axial direction such that each piston ring 6 of the piston 3 is located once in the sensor area of the lubricant sensor 15 per piston stroke, so that a lubricating film thickness in the area of each piston ring 6 can be detected. Analogously to the multiple lubrication points 12, multiple lubricant sensors 15 can also be arranged on the cylinder 2 at a distance from one another in the circumferential direction and/or in the axial direction. This can be particularly advantageous in the case of large compressors in order to cover a sufficiently large area of the cylinder running surface of cylinder 2 . The temporal resolution of the lubricant sensor 15, in particular the ultrasonic sensor, for detecting the measured variable S of the lubricant film can be, for example, 0.01° to 5° crank angle.

The lubrication system control unit 14 is designed according to the invention to

To operate the lubricating system in the operation of the piston compressor 1 at least once in a predetermined calibrating mode and to determine a lubricating film state value SZ based on the lubricating film measured variable S detected during the implementation of the calibrating operating mode. After the end of the calibration operating mode, ie during normal operation of the lubricating system when the piston compressor 1 is in operation, the lubricating system control unit 14 controls the quantity of lubricant to be introduced as a function of the determined lubricating film state value SZ.

As mentioned, the lubrication system is preferably designed for the intermittent introduction of the lubricant, preferably as a pump-to-point system, as a divider block system or as a common rail system. The lubricating system control unit 14 can adjust the amount of lubricant as a function of the determined lubricating film condition value SZ, for example by changing the frequency of the intermittent introduction of the lubricant, and thereby reduce the amount of lubricant compared to the manufacturer's specification. With a corresponding design of the lubrication system, e.g. in a common rail system, the (total) amount of lubricant introduced into the cylinder 2 can also be changed by changing the amount of lubricant per injection of the injector 13 in addition or as an alternative to the frequency change. In the case of pump-to-point or divider block systems, the frequency can be changed, as mentioned, e.g. by increasing the speed of the feed pump(s) of the respective lubrication system.

A sensor value Pi of the measured variable S of the lubricating film is preferably used to determine the lubricating film condition value SZ, which is recorded during a piston stroke of the piston 3 at a point in time at which a piston ring 6 of the piston 3 is in the sensor area of the lubricant sensor 15. The minimum value of the lubricating film measured variable S is preferably used in each case, as shown in FIG. 2 shows an exemplary course of the detected lubricant film measured variable S of a lubricant sensor 15 over the crank angle °KW between the top dead center OT and the bottom dead center UT of the piston 3 in normal operation of the piston compressor 1 (and the lubrication system). The piston 3 corresponds to the embodiment according to FIG. 1 and accordingly has three piston rings 6a, 6b, 6c. Of course, more or fewer piston rings 6 could also be provided. The curve shown corresponds to the measurement signal of the lubricant sensor 15 over the crank angle. As can be seen in FIG. 2, depending on the number i of piston rings 6i, there is a characteristic time profile of the lubricating film measured variable S, which can be used as a measure of the lubricating film thickness of the lubricating film 11 on the cylinder running surface of the cylinder 2.

The curve has a local minimum for each piston ring 6i, which is proportional to the lubricating film thickness of the lubricating film 11 on the cylinder surface when the respective piston ring 6i is in the sensor area of the lubricant sensor 15. In the example shown, these are the minimum values Pa, Pb, Pc, which are generally referred to below as PEAK values Pi within the scope of the invention. The assignment of the PEAK values Pa, Pb, Pc to the respective piston ring 6a, 6b, 6c results according to their arrangement on the piston 3. These PEAK values Pa, Pb, Pc (generally Pi) can now according to the invention in a calibration operating mode of the lubricating system can be used to determine the lubricating film condition value SZ, as explained below with reference to FIGS. 3a+3b.

In principle, however, more than one lubricant sensor 15 could of course also be provided in the lubrication system in order to enable redundant detection of the measured variable S of the lubricating film. The lubricant sensors 15 can, for example, be arranged at a certain angular distance apart in the circumferential direction on the cylinder 2 and/or can be arranged on the cylinder 2 in a distanced manner in the axial direction. Of course, each lubricant sensor 15 is preferably arranged in such a way that all available piston rings 6i of the piston 3 are once in the sensor area of the respective lubricant sensor 15 during a piston stroke. Two lubricant sensors 15 with different positions in the circumferential direction and the same axial positions on the cylinder 2 would result, for example, in qualitatively the same curves of the lubricating film measured variable S, which, however, can differ quantitatively due to the locally different lubricating film thickness of the lubricating film 11 . The PEAK values Pi would

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however, lie at the same crank angle position. On the other hand, two lubricant sensors 15 with different positions in the axial direction and the same positions in the circumferential direction would produce, for example, qualitatively and quantitatively different profiles of the lubricant film measured variable S. In this case, the PEAK values Pi would lie at different crank angle positions. However, the advantageous differential evaluation method of the PEAK value curves, explained in more detail below, would again compensate for the different absolute values of the PEAK values Pi.

For example, the PEAK values Pi may be sampled once every crankshaft revolution or once every piston stroke and stored in the lubrication system control unit 14 . In principle, however, it can also be sufficient if the PEAK values Pi are not recorded uninterruptedly, i.e. not recorded for each crankshaft revolution or each piston stroke and stored for the evaluation of the course over time, but that the PEAK values Pi are recorded intermittently, for example, with a specified interruption duration of a few crankshaft revolutions or, for example, a time of 1 to 60 seconds.

An exemplary calibration operating mode of the lubrication system is described below with reference to FIGS. 3a and 3b. 3b shows a time profile of the amount of lubricant introduced into the cylinder 2 during the calibration operating mode over the crankshaft revolutions of the compressor 1. In FIG. 3a, the example of the first piston ring 6a shows a time profile of the stored PEAK values Pa over the crankshaft revolutions of the compressor 1, which results from the amount of lubricant introduced according to FIG. 3b. A duration of the calibration operating mode can be, for example, at least ten, preferably at least one hundred, particularly preferably at least one thousand crankshaft revolutions of the piston compressor 1 . Since the crankshaft revolutions are proportional to the time, the time can in principle also be plotted on the abscissa.

According to the invention, the calibration operating mode is carried out at least once during operation of the piston compressor 1, for example after a running-in phase during initial commissioning or after a service activity on the compressor 1. The running-in phase typically corresponds to an operating time of 12 to 36 hours. Of course, the calibration operating mode can also be repeated several times in a defined cycle in order to determine an updated lubricating film condition value SZ and to adapt the quantity of lubricant to the updated lubricating film limit value SZ. As a result, different states of wear that occur during operation can be taken into account, which are usually associated with a change in the need for lubricant.

In the calibration operating mode, preferably at least two consecutive time ranges Zi are defined with different quantities of lubricant Mi, and the lubrication system control unit 14 determines a maximum value Pi_max and a minimum value over time for the measured lubricant film variable S recorded during the at least two time ranges, in particular the PEAK values Pi Pi_min and uses this to determine the lubricant film condition value SZ (Fig. 4), which is used to control the amount of lubricant. The maximum value Pi_max and the minimum value Pi_min as well as the associated detection times are preferably determined and stored (at least temporarily). Storage can generally take place, for example, in a suitable memory unit which can be integrated, for example, in the lubrication system control unit 14 or in a superordinate compressor control unit 10. The time ranges Zi and the amounts of lubricant Mi introduced in the time ranges Zi are defined in such a way that different friction and associated wear conditions occur on the cylinder surface, from a fully wetted lubricating film to a partially wetted lubricating film to dry running. The quantity of lubricant M is indicated on the ordinate in the diagram in FIG. 3b as a percentage of a quantity of lubricant specified by the compressor manufacturer.

In the calibration operating mode shown, a first time range Z1 with a predetermined duration and a subsequent second time range Z2 with a predetermined duration are defined only by way of example. The amount of lubricant M1 introduced during the first time period Z1 is preferably defined in such a way that a completely wetted lubricant

film on the cylinder running surface. The amount of lubricant M2 introduced during the second time period Z2, on the other hand, is preferably defined in such a way that dry running occurs on the cylinder running surface. For example, the duration of the first time range Z1 can be at least five crankshaft revolutions and the quantity of lubricant M1 introduced during the first time range Z1 can be 90-200% of a quantity of lubricant specified by the compressor manufacturer. As a result, the maximum value Pa_max is generally in the first time range Z1 and the minimum value Pa_min is generally in the second time range Z2. At the transition between the first time range Z1 and the second time range Z2, there is a characteristic drop in the course of the PEAK values Pa, as can be seen in FIG. 3a.

The duration of the second time range Z2 is preferably also at least five crankshaft revolutions, but can of course also be significantly longer, for example ten, hundred or thousand crankshaft revolutions. The amount of lubricant M2 introduced during the second time period Z2 is preferably 0% of the amount of lubricant specified by the compressor manufacturer, so that no lubricant is introduced. At the end of the second time range Z2, the quantity of lubricant M can be increased again, for example initially to the quantity of lubricant M3 specified by the compressor manufacturer, as indicated by the third time range Z3. In principle, the calibration operating mode is completed after the second time period Z2 and from this point in time the lubrication system control unit 14 can use the lubricating film state value SZ (FIG. 4) determined during the calibration operating mode to control the quantity of lubricant during operation of the piston compressor 1.

[0044] Advantageously, a differential value APa between the determined maximum value Pa_max and the determined minimum value Pa_min is first determined, as shown in FIG. 3a. A lubricating film limit value Pa_limit can now be determined on the basis of maximum value Pa_max and determined difference value APa, which can advantageously be used as lubricating film condition value SZ for controlling the amount of lubricant, as described below with reference to FIG. The limit value Pa_limit can be determined, for example, according to the following relationship:

Pa_limit = Pa_max — k * APa, with a percentage factor K, which can range from 10% to 100%. If several lubricant sensors 15 are provided on a cylinder 2 , then the evaluation and determination of the lubricant film state value SZ, in particular the limit value Pi_limit, is of course preferably carried out for the lubricant film measured variable S of each lubricant sensor 15 . However, mean values of the maximum values Pi_max and the minimum values Pi_min of a number of lubricant sensors 15 could also be used, for example, in order to calculate a mean limit value Pi_limit therefrom. Likewise, an average value could also be formed from a number of limit values Pi_limit and the quantity of lubricant could be controlled on this basis.

In FIG. 4, analogously to FIG . outside of the calibration operating mode). In addition, the maximum value Pa_max and minimum value Pa_min determined beforehand in the calibration operating mode as well as the lubricating film limit value Pa_limit are shown in FIG. The hatched area between the minimum value Pa_min and the lubricating film limit value Pa_limit symbolizes a lubricating system activation area 17. If the lubricating system control unit 14 recognizes that the PEAK value Pa of the measured lubricating film measurement variable S is in the lubricating system activation area 17, the PEAK value Pa ie reaches or falls below the lubricating film limit value Pa_limit, then the lubricating system control unit 14 controls the lubricating system to introduce the lubricant.

This means that no lubricant is introduced into the cylinder 2 via the lubricating point(s) 12 as long as the PEAK value Pa of the detected lubricating film measured variable S is outside the lubricating system activation range 17 (ie above the limit value Pa_limit). Lubricant is only fed back to cylinder 2 when the PEAK value Pa of the

summarized lubricating film measurement variable S is sufficiently low and is in the lubricating system activation range 17 (which is an indicator of insufficient lubricating film thickness of the lubricating film 11). After an injection process of the lubricant has been carried out, the characteristic progression of the lubricant film measured variable S (Fig. 4) will be flatter again, so that the PEAK value Pa is above the limit value. Depending on the lubricant used, the amount of lubricant introduced during the injection process, as well as the operating condition and wear condition of the piston compressor 1, etc., the characteristic course of the lubricating film measured variable S will change again over the crankshaft revolutions, so that the PEAK value Pa slowly returns to the lubrication system activation range 17 approaches.

As soon as the PEAK value Pa falls back into the lubrication system activation range 17, another injection process is triggered by the lubrication system control unit 14, etc. The (total) quantity of lubricant is thus essentially controlled by adjusting the frequency of the individual injections . In common rail systems, in addition to changing the frequency, the amount of lubricant introduced per injection could also be varied. In the case of pump-to-point and divider block systems, on the other hand, the amount of lubricant introduced per injection essentially depends on the design of the delivery unit(s) (e.g. the displacement of a piston pump) and is usually unchangeable. An adjustment of the (total) quantity of lubricant can thus generally only be controlled by adjusting the frequency of the individual injections, for example by changing the speed of the piston pump(s).

The description based on the first piston ring 6a is of course only to be understood as an example and the calibration operating mode could of course also be carried out separately for a number of piston rings 6i. For example, in the calibration operating mode, the course of the measured lubricating film variable S of the lubricant sensor 15 can be evaluated for each piston ring 6i in order to determine a lubricating film state value SZi for each piston ring 6i for controlling the quantity of lubricant. For example, a limit value Pi_limit can be determined for each piston ring 6i, so that an associated lubrication system activation area 17i is determined for each piston ring 6i. The lubricating system control unit 14 can then control the lubricating system to introduce lubricant during normal operation of the piston compressor 1 as soon as the respective PEAK value Pi is in the respectively assigned lubricating system activation range 17 . The limit value Pi_limit can of course also differ.

If, for example, a piston ring 6i has a higher lubricant requirement than another piston ring 6i, then it can in principle also be sufficient if the calibration according to the invention is carried out only for the piston ring 6i with the higher lubricant requirement. The limit value Pi_limit would thus only be determined for one piston ring 6i and the lubricating system control unit 14 would activate the lubricating system accordingly as soon as the assigned PEAK value Pi is in the determined lubricating system activation range 17i. If the lubricating system is suitable for this (for example a common rail system), the introduction of the lubricant is preferably timed in such a way that the lubricant is supplied precisely to the piston ring 6i with the greatest need for lubricant. Depending on the design of the piston ring 6i, the lubricant is preferably introduced during the piston stroke in front of the piston ring 6i or directly onto the piston ring 6i. The piston ring or rings 6i with the lower lubricant requirement consequently automatically receive a sufficiently large amount of lubricant. If the piston compressor 1 has several cylinders 2, then the detection and evaluation of the quantity of lubricant according to the invention preferably takes place individually for each cylinder 2 by arranging at least one lubricant sensor 15 on each cylinder 2.

Furthermore, it can be advantageous if a lubricant quantity detection unit for detecting a quantity of lubricant supplied to the lubrication point 12 is provided in the lubricating system. The lubricant quantity detection unit can be a suitable flow sensor 16, for example, which is integrated in a feed line to a lubrication point 12, as indicated in FIG. The flow sensor 16 is preferably connected to the lubrication system control

tion unit 14 connected to transmit a measurement signal which is proportional to the amount of lubricant. However, a calculation model could also be provided as the lubricant quantity detection unit, for example, which can be implemented in the lubrication system control unit 14, for example, and which calculates the quantity of lubricant supplied to the lubrication point 12 based on available parameters of the lubrication system, e.g. on the basis of a displacement of a piston pump and the pump speed, etc.

The lubrication system control unit 14 can thus compare the lubricant film measurement variable S obtained from the lubricant sensor 15 and the lubricant quantity obtained from the lubricant quantity detection unit in order to check the two values for consistency. As a result, a malfunction of the lubricant sensor 15 can be inferred, for example, if a certain discrepancy between the two values is determined. Likewise, the comparison can be used to detect a leak in the lubrication system. A leak can be present, for example, when the flow sensor 16 outputs a certain expected value and the measured lubricant film variable S detected by the lubricant sensor 15 assumes no value or a very low value. This can mean, for example, that there is a leak between the flow sensor 16 and the lubrication point 12. If, for example, an impermissibly high deviation between the quantity measurement and the measurement of the thickness of the lubricating film (or comparable variables derived from it) is determined, this can be used, for example, as an indicator of a critical operating state of the piston compressor and certain actions can be initiated, such as an alarm signal or a Switching off the compressor 1.

Claims (1)

patent claims A lubricating system for a reciprocating compressor (1) for applying a lubricant to a cylinder surface of a cylinder (2) of the reciprocating compressor (1) in which a piston (3) is reciprocally movable, wherein a lubricating system control unit (14) is provided for controlling an amount of lubricant to be introduced, characterized in that at least one lubricant sensor (15) is provided for detecting a lubricating film measured variable (S) representative of a lubricating film thickness of a lubricating film (11) on the cylinder running surface of the cylinder (2), that the lubricating system - The control unit (14) operates the lubrication system at least once in a predetermined calibration operating mode during operation of the piston compressor (1) and uses the measured lubricant film variable (S) recorded while the calibration operating mode is being carried out to determine a lubricant film condition value (SZ) and that the lubrication system control unit (14 ) after exiting the calibration mode of operation while operating the Kolb enkompressors (1) controls the amount of lubricant to be introduced depending on the determined lubricating film condition value (SZ). 2, lubrication system according to claim 1, characterized in that the lubricant sensor (15) is an ultrasonic sensor, wherein a temporal resolution of the lubricant sensor (15) is preferably 0.01 ° to 5 ° crank angle. 3. The lubricating system according to claim 1 or 2, characterized in that the lubricating system control unit (14) uses a sensor value (Pi) of the lubricating film measured variable (S) to determine the lubricating film condition value (SZ), the detection of which is made during a piston stroke of the piston (3 ) occurs at a time when a piston ring (6i) of the piston (3) is in the sensor area of the lubricant sensor (15), preferably a minimum value of the measured lubricant film variable (S) recorded during the piston stroke. 4. Lubrication system according to one of claims 1 to 3, characterized in that the lubrication system for the intermittent introduction of the lubricant into the cylinder (2) is designed, preferably as a pump-to-point system, as a divider block system or as a common Rail system, and that the lubrication system control unit (14) controls the amount of lubricant by changing a frequency and / or an injection amount of each injection of the intermittent injection of the lubricant. 5. Lubrication system according to one of claims 1 to 4, characterized in that the lubrication system control unit (14) repeats the calibration mode of operation in a specified cycle in order to update the lubricating film condition value (SZ) and to adapt the quantity of lubricant to the updated lubricating film condition value (SZ). 6. Lubrication system according to one of claims 1 to 5, characterized in that the duration of the calibration operating mode is at least ten, preferably at least one hundred, particularly preferably at least one thousand crankshaft revolutions of the piston compressor (1) or an equivalent time. 7. Lubrication system according to one of Claims 1 to 6, characterized in that in the calibration operating mode at least two consecutive time periods (Zi) with different amounts of lubricant (Mi) are defined and in that the lubrication system control unit (14) in a time profile of the at least two Time ranges (Zi) detected lubricant film measured variable (S) determines a maximum value (Pa_max) and a minimum value (Pa_min) and determines the lubricant film condition value (SZ) for controlling the amount of lubricant. 8. Lubrication system according to claim 7, characterized in that a first time range (Z1) with a predetermined duration and a subsequent second time range (Z2) with a predetermined duration are defined and that the quantity of lubricant (M1) introduced during the first time range (Z1) is defined in such a way that a completely wetted lubricating film is formed on the cylinder running surface and the amount of lubricant (M2) introduced during the second time period (Z2) is defined in such a way that dry running occurs on the cylinder running surface, the duration of the first time period (Z1) preferably ZzU- 10 11. 12. 13. 14 Austrian AT 524 547 B1 2022-07-15 is at least five crankshaft revolutions and the quantity of lubricant (M1) introduced during the first time period is 90-200% of a quantity of lubricant specified by the compressor manufacturer and the duration of the second time period (Z2) is preferably at least five crankshaft revolutions and the quantity of lubricant introduced during the second time period (Z2). (M2) is 0% of the amount of lubricant specified by the compressor manufacturer. Lubrication system according to Claim 7 or 8, characterized in that the lubrication system control unit (14) determines a difference value (APa) between the determined maximum value (Pa_max) and the determined minimum value (Pa_min), from the maximum value (Pa_max) and the determined difference value ( APa) determines a lubricating film limit value (Pa_limit) and uses the lubricating film limit value (Pa_limit) as a lubricating film condition value (SZ) and that the lubrication system control unit controls the lubrication system for introducing the lubricant during operation of the piston compressor (1) after the end of the calibration operating mode if the lubricating film measured variable (S) lies in a lubrication system activation range (17) between the minimum value (Pa_min) and the lubricating film limit value (Pa_limit). Lubrication system according to one of Claims 1 to 9, characterized in that a lubricant quantity detection unit (16) is provided in the lubrication system for detecting a quantity of lubricant supplied to the lubrication point (12) and that the lubrication system control unit (14) receives the data from the lubricant film sensor (15) Received lubricant film variable (S) and the quantity of lubricant obtained from the lubricant quantity detection unit compares to check the two values for consistency and / or to detect a leak in the lubrication system. Piston compressor (1) with a number of cylinders (2), in each of which a piston (3) can be moved back and forth, and with a lubricating system for supplying the number of cylinders (2) with a lubricant, the number of cylinders being proportional to the number of cylinders (2) at least one lubricating point (12) is provided for introducing the lubricant onto a cylinder running surface of the cylinder (2), characterized in that the lubricating system is designed according to one of Claims 1 to 10. Piston compressor (1) according to Claim 11, characterized in that a plurality of lubrication points (12) and/or a plurality of lubricant sensors (15) are provided on at least one cylinder (2), with preferably a plurality of lubrication points (12) and/or lubricant sensors (15) in Circumferential direction of the at least one cylinder (2) are provided and / or multiple lubrication points (12) and / or lubricant sensors (15) are provided in the axial direction of the at least one cylinder (2). Method for operating a piston compressor (1) with at least one cylinder (2), in which a piston (3) is moved back and forth, wherein a lubricant is supplied to a cylinder running surface of the at least one cylinder (2) by means of a lubrication system and wherein a The quantity of lubricant supplied is controlled by a lubrication system control unit (14), characterized in that a lubricant film measured variable (S) representative of a lubricant film thickness of a lubricant film (11) on the cylinder running surface of the cylinder (2) is detected by means of at least one lubricant sensor (15). that the lubrication system is operated at least once in a predetermined calibration operating mode by the lubrication system control unit (14) during operation of the piston compressor (1), a lubrication film condition value (SZ) being determined on the basis of the measured lubricant film variable (S) recorded while the calibration operating mode is being carried out and that the lubrication system control unit t (14) controls the quantity of lubricant to be introduced as a function of the lubricant film condition value (SZ) determined during operation of the piston compressor (1) after the end of the calibration operating mode. Method according to Claim 13, characterized in that an ultrasonic sensor is used as the lubricant sensor (15), the temporal resolution of the lubricant sensor preferably being 0.01° to 5° crank angle. 15. The method according to claim 13 or 14, characterized in that a sensor value (Pi) of the lubricating film measured variable (S) is used to determine the lubricating film state value (SZ), which is recorded during a piston stroke of the piston (3) at a point in time to which a piston ring (6) of the piston (3) is located in the area of the lubricant sensor (15), preferably a minimum value of the measured lubricant film variable (S) recorded during the piston stroke. 16. The method according to any one of claims 13 to 15, characterized in that the lubricant is introduced intermittently into the cylinder (2) and that the lubricating system control unit (14) adjusts the amount of lubricant by changing a frequency and/or an injection amount of each injection the intermittent introduction of the lubricant controls. 17. The method according to any one of claims 13 to 16, characterized in that the calibration operating mode is repeated in a fixed cycle to update the lubricating film condition value (SZ) and to adapt the lubricant quantity to the updated lubricating film condition value (SZ) and/or that the calibration operating mode at least ten, preferably at least one hundred, particularly preferably at least one thousand crankshaft revolutions of the piston compressor (1) or an equivalent time is carried out. 18. The method according to any one of claims 13 to 17, characterized in that in the calibration operating mode in at least two consecutive time periods (Zi) different amounts of lubricant (Mi) are introduced into the cylinder (2) and that the lubrication system control unit (14) in a time A maximum value (Pa_max) and a minimum value (Pa_min) are determined during the at least two time periods (Zi) of the lubricating film measured variable (Mi) and the lubricating film state value (SZ) for controlling the quantity of lubricant is determined therefrom. 19. The method according to claim 18, characterized in that a first time range (Z1) with a predetermined duration and a subsequent second time range (Z2) with a predetermined duration are defined and that the amount of lubricant (M1) introduced during the first time range (Z1) is determined in such a way that a completely wetted lubricating film forms on the cylinder running surface and the amount of lubricant (M2) introduced during the second time range (Z2) is determined such that dry running occurs on the cylinder running surface, with the duration of the first time range (Z1) is preferably at least five crankshaft revolutions and the quantity of lubricant (M1) introduced during the first time range (Z1) is 90-200% of a quantity of lubricant specified by the compressor manufacturer and the duration of the second time range (Z2) is preferably at least five crankshaft revolutions and the quantity introduced during the second time range grease Lubricant quantity (M2) 0% of the lubricant quantity specified by the compressor manufacturer. 20. The method according to claim 18 or 19, characterized in that a difference value (APa) between the determined maximum value (Pa_max) and the determined minimum value (Pa_min) is determined, from the maximum value (Pa_max) and the determined difference value (APa) a lubricating film limit value (Pa_limit) is determined and the lubricating film limit value (Pa_limit) is used as the lubricating film state value (SZ) and that the lubricating system control unit controls the lubricating system to introduce lubricant after the end of the calibration operating mode if the lubricating film measured variable (S) is between the minimum value (Pa_min) and the lubricating film limit value (Pa_limit) lies in the lubricating system activation range (17). 3 sheets of drawings