• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Method for condition monitoring of at least one hydraulic pump (2) of a hydraulic system of a forming machine (1), wherein the at least one hydraulic pump (2) is connected to at least one pressure line (3) and adapted to provide a pressure (p) in the at least one a pressure line (3) to be operated with a displacement volume (v) or a rotational speed, wherein the displacement volume (v) or the rotational speed of the at least one hydraulic pump (2) is suddenly changed and by analyzing a temporal reaction of the pressure (p) in the at least one hydraulic pump (2) and / or in the at least one pressure line (3) a state of the at least one hydraulic pump (2) is determined.
    公开号:AT521016A4
    申请号:T50724/2018
    申请日:2018-08-24
    公开日:2019-10-15
    发明作者:Ing Dr Kurt Pichler Dipl;Ing Dr Rainer Haas Dipl;Ing Dr Pascal Bader Dipl;Ing Dr Friedrich Johannes Kilian Dipl
    申请人:Engel Austria Gmbh;
    IPC主号:
    专利说明:

    The invention relates to a method and a device for condition monitoring of at least one hydraulic pump of a hydraulic system of a shaping machine having the features of the preamble of claim 1 and of claim 6, respectively.
    Hydraulic pumps wear for various reasons, in particular by friction on contact surfaces and increased abrasion due to particles of different sizes in the hydraulic oil.
    For internal gear pumps, this wear, for example, the abrasion of the contact surface between
    - the teeth of the internal and external gear,
    - the tooth tips and the filling piece,
    - the internal and external gear and the axial sealing washers,
    - be the external gear and the housing (radial and axial).
    In piston pumps can be an example of abrasion
    - between piston and cylinder
    - At the reception of the cylinder
    - done on the control disc.
    In particular, the abrasion of metal particles, high rotational speeds, cavitation, poor oil quality and a long service life of the wear of the hydraulic pump is further favored. A hydraulic pump is therefore a drive system with a certain life, which is to be replaced after a certain time.
    The main effect of increasing wear is an increase in hydraulic pump leaks. These leaks are caused by the Abriebe above, which lead to increase the gap dimensions and therefore to a deteriorated seal of the components to each other.
    / 23
    82084 36 / eh
    Generic methods and devices are evident from the following documents:
    DE 101 56 927 A1 describes a device for controlling and monitoring pumps, in particular worm pumps, in industrial plants. Various wear-relevant operating parameters are recorded by means of sensors and an expected value of the operating time is calculated on the basis of the acquired operating parameters. Operating parameters are:
    - Temperature differences and absolute temperatures
    - Pressure differences and absolute pressures
    - Back pressure differences and absolute back pressures
    - Absolute suction pressure
    - flow rates
    - Rotation speed
    - Torque
    - flow
    - Viscosity of the (hydraulic) medium
    - Density of the (hydraulic) medium
    - Electric variables of a pump, such as current, voltage, power consumption, phase shift
    DE 10 2005 059 564 A1 shows a device for condition monitoring in the case of hydrostatic displacement units, in particular axial piston pumps. A multitude of sensor, overgrowth and operating data are analyzed and thus the condition of the machine is diagnosed. A possible maintenance of the machine is displayed before its due date. The following parameters are monitored:
    - surface vibrations
    - The hydraulic fluid and leak oil temperature
    the hydraulic fluid condition (degree of soiling, viscosity and dielectric values)
    - The speed of a cylinder drum / 23
    82084 36 / eh
    - the pressure in high and low pressure lines
    DE 10 2004 028 643 B3 discloses a device for monitoring a pump system with at least one pump. The state variables of the pump (s) are detected by structure-borne sound vibrations of the pump (s). Threatening or already existing disturbances are recognized and announced by the device. The monitored state variables are:
    - cavitation
    - dry running
    - Air content of the (hydraulic) medium
    - Condition of the discharge side of the pump (open or closed)
    The aforementioned methods and devices require a sometimes very complex additional sensors.
    In DE 10 2008 035 954 A1 a monitoring of a displacement machine is described. It detects a system pressure gradient using a position-changing displacer and then compares it with an expected system pressure history to detect malfunctions. In addition, an imminent damage of the pump is detected early. The evaluation process is relatively complex.
    The object of the invention is to provide a generic method and a generic device in which no additional sensors are required and which do not require a complex evaluation process.
    This object is achieved by a method having the features of claim 1 or by an apparatus having the features of claim 6. Advantageous embodiments of the invention are defined in the dependent claims.
    According to the invention it is provided that the displacement volume or the rotational speed of the at least one hydraulic pump is changed suddenly and by an analysis of a temporal reaction of the pressure in the at least one hydraulic pump / 23
    82084 36 / eh and / or in the at least one pressure line, a state of the at least one hydraulic pump is determined.
    By the invention, it is possible to have a state of at least one
    Hydraulic pump, in particular a leak to determine (wear measurement).
    For this purpose, the at least one hydraulic pump is as far as possible decoupled hydraulically from the remaining hydraulic components of the hydraulic system and a leakage measurement is carried out. The better the hydraulic decoupling (eg by a blocking element such as a lockable valve) works, the more accurate the result of the leakage measurement.
    Since it is in the inventive type of wear measurement to a
    Leakage measurement is corrupted, the wear calculation, if there is an unrecognized leak in the hydraulic system outside the at least one hydraulic pump (eg, on a locking member used for decoupling the at least one hydraulic pump), which is not recognized and taken into account.
    For the monitoring of the at least one hydraulic pump, preferably only the pressure and the displacement volume or the rotational speed of the at least one hydraulic pump are detected. Because in conventional hydraulic systems sensors are anyway provided, by which the pressure in the at least one hydraulic pump and / or the at least one pressure line and the displacement volume or the speed can be determined (eg pressure directly on the at least one hydraulic pump or on a valve block and Speed or displacement volume over the motor angle and the time), the invention does not require additional sensors.
    The invention makes it possible to define failure limits. This can be z. Example by supplied by the manufacturer of at least one hydraulic pump values, or it can be determined by the manufacturer or operator of the molding machine, from which value of leakage, the at least one hydraulic pump provides only an unacceptable performance.
    / 23
    82084 36 / eh
    The determination of the state can be carried out on the basis of the method carried out according to the invention in various ways, for. B. (individually or in any combination):
    by comparison with previous measurements of the same forming machine
    by comparison with measurements of other shaping machines (preferably by comparison with a statistical mean or median)
    - by comparison with theoretical calculations or computer simulations
    - by comparison with data sheet values (of the manufacturer)
    In a first preferred embodiment of the method according to the invention, at least the following steps are provided:
    - Operating the at least one hydraulic pump with a predetermined, preferably constant, course of the pressure in the at least one hydraulic pump and / or in the at least one pressure line
    - Sudden reduction of the displacement volume or the speed of the at least one hydraulic pump, preferably to the value zero or to a predetermined value or curve of the pressure in the at least one hydraulic pump and / or the at least one pressure line, with shut pressure line
    - Measuring a pressure reduction time or determining a representative of the pressure reduction size, which is required for the pressure reduction in the at least one hydraulic pump and / or in the at least one pressure line
    Determining a state of the at least one hydraulic pump by analyzing the pressure reduction time or the quantity representative of the pressure reduction
    If the measured or determined pressure reduction is too fast (the measured or determined pressure reduction time is too short), this indicates leakage, which is the main manifestation of wear. The representative of the pressure reduction size may be, for example, a combination of time and dynamic behavior, for. B. to take into account a time derivative of the pressure curve.
    / 23
    82084 36 / eh
    In a particularly preferred second embodiment of the method according to the invention, at least the following steps are provided:
    - Sudden increase of the displacement volume or the speed of the at least one hydraulic pump, preferably from zero, to a predetermined value or course of the pressure in the at least one hydraulic pump and / or the at least one pressure line with shut-off pressure line
    - Measuring a pressure build-up time or determining a representative of the pressure build-up size, which is required for the pressure build-up in the at least one hydraulic pump and / or in the at least one pressure line
    - Determining a state of the at least one hydraulic pump by analyzing the pressure build-up time or the representative of the pressure build-up size
    If the measured or determined pressure build-up is too slow (the measured or established pressure build-up time is too long), this indicates leakage, which is the main manifestation of wear. For example, the size representative of pressure build-up may be a combination of time and dynamic behavior, e.g. B. to take into account a time derivative of the pressure curve.
    A device according to the invention is characterized by:
    - An input to which a pressure signal of a pressure sensor of the hydraulic system can be fed
    a clock providing a time signal
    - An analysis unit which is connected to the input or can be brought to the input in a data transmitting connection and which is adapted from the pressure signal and the time signal of the clock by analyzing a temporal reaction of the pressure in the at least one hydraulic pump and / or in the at least one pressure line, preferably after one
    Embodiment of the method according to the invention to determine the state of at least one hydraulic pump.
    / 23
    82084 36 / eh
    The shutting off the pressure line can by a suitable locking member, for. B. by a shut-off valve (or a slider or the like.) Take place, which can be arranged in a valve block.
    The method according to the invention can be carried out within a few seconds.
    The at least one hydraulic pump is preferably measured automatically in a defined measuring cycle. The measuring cycle can be started in different ways (individually or in any combination):
    - Triggered by a machine control of the molding machine, z. At fixed intervals of operating hours
    - remote controlled release, z. Via a cloud or service application
    - Triggered by a service technician or an operator of the molding machine
    - triggered by an algorithm
    In one exemplary embodiment of the method according to the invention, it is provided that for determining the state of the at least one hydraulic pump it is additionally analyzed how high a speed or a displacement volume required for maintaining a steady-state pressure in the at least one hydraulic pump and / or in the at least one pressure line the at least one
    Hydraulic pump is. The higher the speed or displacement required to maintain a steady-state pressure, the greater the wear or leaks. A calculation of a possible leakage during the holding of the steady-state pressure is possible due to the relationship between the leakage and the speed of the at least one hydraulic pump (since the delivery rate of the at least one hydraulic pump with the pressure line shut off is zero). This applies regardless of the pump type (in particular, regardless of whether the displacement volume is constant or variable).
    The invention can constant pumps (here is only the speed than
    Intervention parameters available because the displacement volume is indeed constant) or variable displacement (here are speed and displacement volume, for example / 23
    82084 36 / eh influenced by adjusting a swivel angle, available) are used.
    The invention is preferably used in internal gear pumps and / or axial piston pumps.
    The invention is preferably used in variable-speed hydraulic pumps and / or pressure-controlled hydraulic pumps.
    The invention preferably takes the form of molding machines in the form of
    Injection molding machines, in particular plastic injection molding machines, are used.
    The result of the wear measurement according to the invention can be recorded.
    The result of the wear measurement according to the invention can be used in various ways (individually or in any combination):
    - Display of the result of the wear measurement to the customer (eg in a customer portal, in the controller, by e-mail, in the cloud, ...). He can use this information to set further actions independently (eg planning a removal or a machine shutdown)
    - Parameterization of the forming machine (eg control or control parameters, pump delivery characteristics, pilot control parameters for controlled machine movements, switching times of valves,.)
    - Parameterization of the forming process (eg control or control parameters for the correction of the forming process,.)
    - as input for further algorithms (eg wear detection of hydraulic components such as valves, cylinders, etc., oil identification, ...)
    - to trigger a service call or change the service interval,
    - For more detailed analysis of the state of at least one hydraulic pump
    - Determination of the efficiency and thus the losses in the at least one hydraulic pump
    - Triggering of business processes / 23
    82084 36 / eh
    Embodiments of the invention will be discussed with reference to the figures. Show it:
    Fig. 1 is a first shaping machine with an inventive
    contraption
    Fig. 2 shows a second forming machine with an inventive
    contraption
    Fig. 3 shows a device according to the invention
    4 shows a first pressure curve over time
    5 shows a second pressure curve over time
    Fig. 1 shows a forming machine 1, in particular injection molding machine, with a hydraulic system. By way of example only two branches or circles are shown by the hydraulic system. Each circuit comprises a supply line 7, a hydraulic pump 2 which can be driven by a motor 6, a pressure line 3 connected to the hydraulic pump 2 and which leads to a component 9 to be supplied with hydraulic oil
    Forming machine 1 leads and a return 8. Each pressure line 3 is shut off via a switchable valve 4. The valves 4 are arranged by way of example in a valve block 5. The exact design of the hydraulic system is not important.
    Of importance is the inventive device 10 for condition monitoring of the hydraulic pumps 2 of the hydraulic system of the molding machine 1. A possible internal structure thereof is shown in Fig. 3.
    The device 10 receives via signal lines signals which are characteristic of the pressure in the pressure lines 3 and the hydraulic pumps 2. It can control the motors 6 of the hydraulic pumps 2 and the valves 4 of the valve block 4 via signal lines.
    In the embodiment shown, the device 10 forms part of
    Forming machine 1 and z. B. be realized in the machine control. As the embodiment of FIG. 2 shows, the device 10 can also be separated from the forming machine 1, z. B. away from this, be arranged and / 23
    82084 36 / eh via a data-transmitting connection, z. B. a cloud 15 with the
    Shaping machine 1 (eg with its machine control) via a
    Communication unit 14 are in communication.
    The device 10 has, according to FIG. 3, an input 11 to which a pressure signal of a pressure sensor of the hydraulic system and / or a signal for calculating the rotational speed or the displacement volume v of the hydraulic pumps 2 can be supplied, a clock 12 providing a time signal (each device having a Time signal outputs can be understood as clock 12, it does not have to be a separate component in the device 10), an output 16 and an analysis unit 13. The analysis unit 13 is connected to the input 11 or, unlike the one shown, could be brought into a data-transmitting connection with the input 11. It is designed to determine the state of the at least one hydraulic pump 2 from the pressure signal of the pressure sensor and the time signal of the clock 12. This can be done as discussed with reference to FIGS. 4 and / or 5.
    4 shows a method for monitoring the condition of at least one hydraulic pump of a hydraulic system of a forming machine 1 (eg as shown in Fig. 1 and / or 2), wherein the at least one hydraulic pump 2 is connected to at least one pressure line and is adapted thereto to be operated for providing a pressure p in the at least one pressure line 3 with a displacement volume v. The corresponding control commands may be output from a machine controller of the forming machine 1 or from the apparatus 10. Starting from an operation of the at least one hydraulic pump 2 with a constant pressure p in the at least one hydraulic pump 2 and / or in the at least one pressure line 3, the at least one pressure line 3 connected to the at least one hydraulic pump 2 is shut off at a certain point in time abruptly reducing the displacement volume v, preferably to the value "zero" (both controlled by the device 10 via corresponding control commands). It is the pressure-reduction time t from (is in a range of a few hundred milliseconds) was measured, which is for pressure reduction in the at least one hydraulic pump 2 and / or in which at least requires a pressure line. 3 This is done in / 23
    82084 36 / eh
    Analysis unit 13 of the device 10 based on the time signal of the clock 12 and the pressure signal of the pressure sensor. By analyzing the pressure reduction time t ab , the state of the at least one hydraulic pump 2 in the analysis unit 13 can be determined.
    Alternatively or additionally, it is possible to proceed as shown in FIG. At a certain point in time, the at least one pressure line 3 connected to the at least one hydraulic pump 2 is shut off and a sudden increase in the displacement volume v, preferably from zero, to a predetermined value v (both controlled by the device 10 via corresponding control commands). The pressure build-up time t is measured, which is required for the pressure build-up in the at least one hydraulic pump 2 and / or in the at least one pressure line 3. This is done in the analysis unit 13 of the device 10 on the basis of the time signal of the clock 12 and the pressure signal of the pressure sensor. By analyzing the pressure build-up time t on , the state of the at least one hydraulic pump 2 can be determined. Alternatively, the displacement volume v (or the rotational speed) could be increased until reaching a predetermined value of the pressure p in the at least one hydraulic pump 2 and / or the at least one pressure line 3.
    In addition, in the method of FIGS. 4 and / or 5 for determining the state of the at least one hydraulic pump 2, it can be analyzed how high one for holding a stationary pressure p in the at least one hydraulic pump 2 and / or in the at least one pressure line 3 Required speed of the at least one hydraulic pump 2 is. The higher the speed required to hold a steady state pressure p, the higher the leakage.
    / 23
    82084 36 / eh
    LIST OF REFERENCE NUMBERS
    forming machine
    hydraulic pump
    Pressure line lockable valve
    manifold
    Motor of the hydraulic pump
    Flow of the hydraulic system
    Return of the hydraulic system with hydraulic oil to be supplied components of the molding machine
    Device for condition monitoring
    Input of the condition monitoring device
    Clock of the condition monitoring device
    Analysis unit of the condition monitoring device
    Communication unit of the forming machine
    Cloud
    Output of the condition monitoring device p Pressure in the pressure line and / or the hydraulic pump v Displacement volume t from pressure reduction time t to pressure build-up time
    权利要求:
    Claims (8)
    [1]
    claims:
    1. A method for condition monitoring at least one hydraulic pump (2) of a
    Hydraulic system of a forming machine (1), wherein the at least one hydraulic pump (2) with at least one pressure line (3) is connected, and is adapted to provide a pressure (p) in the at least one pressure line (3) with a displacement volume (v ) or a rotational speed, characterized in that the displacement volume (v) or the rotational speed of the at least one hydraulic pump (2) is suddenly changed and by an analysis of a temporal reaction of the pressure (p) in the at least one hydraulic pump (2) and / or in the at least one pressure line (3), a state of the at least one hydraulic pump (2) is determined.
    [2]
    A method according to the preceding claim, comprising the following steps:
    Operation of the at least one hydraulic pump (2) with a predetermined, preferably constant course of the pressure (p) in the at least one hydraulic pump (2) and / or in the at least one pressure line (3)
    Sudden reduction of the displacement volume (v) or the rotational speed of the at least one hydraulic pump (2), preferably to the value zero or to a predetermined value or course of the pressure in the at least one hydraulic pump and / or the at least one pressure line, with shut-off pressure line ( 3)
    - Measuring a pressure reduction time (t from ) or determining a representative of the pressure reduction size, which is required for the pressure reduction in the at least one hydraulic pump (2) and / or in the at least one pressure line (3)
    - Determining a state of the at least one hydraulic pump (2) by analyzing the pressure reduction time (t ab ) or the representative of the pressure build-up size
    [3]
    3. Method according to one of the two preceding claims, comprising the following steps:
    14/23
    82084 36 / eh
    Sudden increase of the displacement volume (v) or the rotational speed of the at least one hydraulic pump (2), preferably from zero, to a predetermined value or course of the pressure (p) in the at least one hydraulic pump (2) and / or the at least one pressure line ( 3) with shut off pressure line (3)
    - Measuring a pressure build-up time (t on ) or determining a representative of the pressure build-up size, which is required for the pressure build-up in the at least one hydraulic pump (2) and / or in the at least one pressure line (3)
    - Determining a state of the at least one hydraulic pump (2) by analyzing the pressure build-up time (t on ) or the representative of the pressure build-up size
    [4]
    4. The method according to at least one of the preceding claims, wherein for the
    Determining the state of the at least one hydraulic pump (2) additionally analyzes how high a displacement volume (v) required for maintaining a steady-state pressure (p) in the at least one hydraulic pump (2) and / or in the at least one pressure line (3) or a required speed of the at least one hydraulic pump (2).
    [5]
    5. The method according to at least one of the preceding claims, wherein the
    Result of the method is used in the following manner, individually or in any combination:
    - Display of the result of the analysis and / or deriving the efficiency
    - Calculation of the power loss
    - as a decision support for a maintenance planning
    - Parameterization of the forming machine
    - Parameterization of the molding process
    - as input for further algorithms
    - to trigger a service call or change the service interval
    [6]
    6. Device (10) for condition monitoring at least one hydraulic pump (2) of a hydraulic system of a forming machine (1), wherein the at least
    15/23
    A hydraulic pump (2) is connected to at least one pressure line (3) and is designed to be operated with a displacement volume (v) or rotational speed to provide a pressure (p) in the at least one pressure line (3) , marked by:
    - An input (11) to which a pressure signal of a pressure sensor of the hydraulic system can be fed
    a clock providing a time signal (12)
    - An analysis unit (13) which is connected to the input (11) or can be brought to the input (11) in a data-transmitting connection and which is adapted from the pressure signal of the pressure sensor and the time signal of the clock (12) by a Analysis of a temporal reaction of the pressure (p) in the at least one hydraulic pump (2) and / or in the at least one pressure line (3), preferably according to a method according to at least one of the preceding claims, the state of the at least one hydraulic pump (2) determine.
    [7]
    7. Device according to the preceding claim, wherein the analysis unit (13) is adapted to take into account for determining the state of the at least one hydraulic pump (2) a displacement volume (v) or a rotational speed of the at least one hydraulic pump (2).
    [8]
    8. Forming machine (1), in particular injection molding machine, with a hydraulic system, which has at least one, with at least one pressure line (3) connected to the hydraulic pump (2), and either a device (1) according to at least one of the preceding claims or with such can be brought into a data-transmitting connection.
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    同族专利:
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE102006001585A1|2006-01-12|2007-07-19|Rehau Ag + Co.|Method for monitoring the wear of pumps and pump for carrying out the method|
    DE102006014269A1|2006-03-28|2007-10-04|Robert Bosch Gmbh|Hydraulic system`s functional test providing method for brake assembly of vehicle, involves measuring delivery rate of multi-piston pump, where multi-piston pump is tested at same time to check operability of individual pistons|
    DE102007007005A1|2007-02-08|2008-08-14|Robert Bosch Gmbh|Electrohydraulic control arrangement|
    EP3211275A1|2016-02-26|2017-08-30|Mitsubishi Heavy Industries, Ltd.|Method and system for diagnosing hydraulic machine, hydraulic machine, and renewable-energy type power generating apparatus|CN111964319A|2020-08-21|2020-11-20|中车青岛四方车辆研究所有限公司|Compressor running frequency compensation method and system|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50724/2018A|AT521016B1|2018-08-24|2018-08-24|Method and device for condition monitoring of a hydraulic pump|ATA50724/2018A| AT521016B1|2018-08-24|2018-08-24|Method and device for condition monitoring of a hydraulic pump|
    DE102019117820.7A| DE102019117820A1|2018-08-24|2019-07-02|Method and device for monitoring the condition of a hydraulic pump|
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