• 专利附录
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    • 专利摘要:
    Method for determining a target value of a state variable - in particular a dynamic pressure (MPP) - of a mixture (1) of a molding compound and a gas intended for a molding process, wherein - the mixture (1) of the molding compound and the gas at different test values of the State variable is provided, - the mixture (1) present for the different test values of the state variable is compressed or decompressed at least once, - during compression or decompression, at least the state variable of the mixture (1) and / or at least one further state variable of the mixture ( 1) is measured directly or indirectly, - from measured values of the state variable and / or the at least one further state variable, determination values of a compression behavior variable characteristic of the compression behavior of the mixture (1) are determined, and - a criterion aimed at a state of dissolution of the gas in the molding compound is checked becomes, whereby anha nd the test values and the determination values are inferred from a lowest or highest value of the state variable at which the gas in the molding compound is in solution, and this lowest or highest value of the state variable at which the gas in the molding compound is in solution as to determining target value of the state variable is used.
    公开号:AT522379A1
    申请号:T50853/2019
    申请日:2019-10-08
    公开日:2020-10-15
    发明作者:
    申请人:Engel Austria Gmbh;
    IPC主号:
    专利说明:

    The present invention relates to a method and a computer program product for determining a setpoint value of a state variable - in particular a dynamic pressure - of a mixture of a molding compound and a gas intended for a molding process, as well as a molding method and
    a shaping machine with a machine control.
    It is known to use a gas added to the molding compound in molding processes. For example, in the molding process offered by the applicant under the label MuCell, foamed molded parts are produced by adding a gas to a plastic melt. It is a direct gassing process. There is a mixture of the molding compound and the gas in a plasticizing cylinder, with so much pressure from a plasticizing screw
    to be exercised on the mixture that the gas is in solution in the molding compound.
    If the gas is not in solution, i.e. If gas bubbles are present in the plastic melt, these gas bubbles can cause bubbles, gas cushions or streaks in the component produced (solidified) by the plastic molding process. Further consequences can be severe delay, i.e. be strong deviations from the desired component geometry, up to explosive bursting of the gas cushions mentioned. These negative consequences lead to the corresponding components
    are unusable and must be declared as scrap.
    In practice, the back pressure is set too high to be on the safe side, which is obviously disadvantageous because the energy consumption is increased (to generate the pressure that is too high) and the wear and tear on all components involved, but in particular the plasticizing screw, is increased, just one lower throughput when plasticizing
    is achieved and higher fiber breakage occurs in fiber-reinforced plastics.
    It is generally known that there is a connection between the compression modulus on the one hand and the question of whether the gas is in solution in the molding compound on the other. In AT 520733 B1 this connection was used to
    to determine whether the gas is in solution for a specific plastic melt.
    A special application is also known from DE 10 2007 030 637 A1, in which, by determining a compression module, a quantitative ratio of a powder component and a binder component of an injection-mouldable mass is deduced
    becomes.
    The prior art described here relates to plastic injection molding. Similar situations and problems arise in general shaping processes
    also on.
    The object of the present invention is to provide a method and a computer program product which make it possible to reduce wear and / or energy consumption when performing the shaping process, avoiding the process with undissolved gas in the
    To operate molding compound.
    With regard to the method, this object is achieved with the features of claim 1
    solved. This is done by
    - the mixture of the molding compound and the gas is provided with different test values of the state variable,
    - the mixture present for the different test values of the state variable is compressed or decompressed at least once,
    - During compression or decompression, at least the state variable of the mixture and / or at least one further state variable of the mixture is measured directly or indirectly,
    - determination values of a compression behavior variable characteristic of the compression behavior of the mixture are determined from measured values of the state variable and / or the at least one further state variable, and
    - A criterion directed to a state of solution of the gas in the molding compound is checked, as a result of which a lowest or highest value of the state variable is concluded on the basis of the test values and the determination values
    which the gas in the molding compound is in solution, and this is the lowest or highest
    Value of the quantity of state at which the gas in the molding compound is in solution than to
    determining target value of the state variable is used.
    With regard to the computer program product, the object is achieved by the features of claim 17. This is done through commands that cause an executing computer to
    - to control at least one device in such a way that the mixture of the molding compound and the gas that is present with different test values of the state variable is provided,
    - to control the device in such a way that the mixture present for the different test values of the state variable is compressed or decompressed at least once,
    - to receive measured values of at least one sensor, which at least one sensor directly or indirectly measures the state variable and / or at least one further state variable during the compression or decompression of the mixture,
    to determine from the measured values determination values of a compression behavior variable characteristic of a compression behavior of the mixture, and
    - to check a criterion directed to the state of the gas in the molding compound, whereby, on the basis of the test values and the determination values, a conclusion is drawn as to a lowest or highest value of the state variable at which the gas in the molding compound is in solution, and this lowest dynamic pressure,
    in which the gas is in solution, to be output as dynamic pressure to be determined.
    The device addressed here can be a dedicated device for performing a method according to claim 1. However, an embodiment can be preferred in which a molding machine is used as the device, which is also used for
    Carrying out the shaping process is provided.
    The executing computer can be a machine control unit of
    Be a molding machine.
    For the purposes of this document, the terms
    "Shaping process" and "shaping method" used interchangeably.
    The mixture according to the invention is to be understood as at least one mixture. This means that a single mixture can be used for different test values of the state variable or different mixtures can be provided for different test values of the state variable. It would be correct to distinguish between the mixture which is intended for the shaping process and the mixture or the mixtures which are provided according to the method according to the invention. In this document, however, the singular and plural of
    Mixture (s) used interchangeably.
    Protection is also sought for a molding process, with a method according to the invention for determining the setpoint value of the state variable - in particular the back pressure - of a mixture of a molding compound and a gas and the setpoint value of the state variable as a predetermined setpoint value for
    the molding process is used.
    Protection is also desired for a molding machine with a machine control unit which is set up for the molding machine
    to cause a method according to the invention to be carried out.
    Shaping machines can be understood to mean injection molding machines, transfer presses, presses or the like. Molding processes / molding processes can include plastic molding processes, in particular injection molding processes, injection molding processes or reactive plastic molding processes,
    but also pressing and other casting processes and the like are understood. The invention makes it possible to optimize the target value for the state variable (i.e. depending on
    according to the state variable to minimize or maximize), whereby a
    Sets energy savings.
    In the case of back pressure as a state variable to be minimized according to the invention, wear on a plasticizing screw can also be reduced, the throughput, i.e. the plasticizing performance, can be increased and with fiber-reinforced plastics the
    Fiber breakage can be reduced.
    However, the invention can also be used advantageously for optimizing a temperature of the mixture as a state variable. A possibly slightly impaired flowability of the mixture is achieved in many cases by the
    Energy savings outweighed.
    For example, when using carbon dioxide as a gas, the solubility decreases with increasing temperature. In such a case, the method according to the invention could also be used to find an increased temperature for the mixture at which, on the one hand, the gas is dissolved in the molding compound and, on the other hand, a
    Improvement of the flow properties can be achieved.
    “Optimizing” (or “minimizing” or “maximizing”) does not necessarily mean finding an actual optimum in the mathematical sense. Rather, it is about an improved one from a technical point of view
    To find the value for the state variable
    The molding compound can be a - preferably thermoplastic -
    Trade plastic melt.
    The state variable (and the further state variable) of the mixture can be understood as a thermodynamic state variable. But it does not concern them
    (chemical) composition of the mixture.
    The state variable can preferably be a pressure or a temperature. In this document, the expression "dynamic pressure" is used for the state variable pressure. Although this term comes from plastic injection molding, it is used here generally as a print of the mixture of the
    Molding compound and the gas are understood.
    However, modified state variables can also be used. A trivial example would be the inverse dynamic pressure, in which case, according to the invention, a highest value for this state variable would have to be found instead of the lowest value, as in the case of
    Dynamic pressure itself as a state variable.
    The at least one further state variable to be measured can preferably also be
    Volume can be used.
    Within the scope of the invention, in principle all intensive state variables can be used as the state variable or the at least one further state variable.
    Ultimately, it is also conceivable to use extensive state variables in this way.
    The gas for the mixture can in particular be an inert gas (physical
    Foaming), for example molecular nitrogen or carbon dioxide.
    In certain applications, however, the invention can also be used advantageously with chemical blowing agents. This applies in particular to propellants, which on the one hand release a lot of gas and on the other hand are used in high concentrations
    will.
    In the method according to the invention, measurements are carried out during the compression or decompression for the mixtures which are present at different test values of the state variable, and the determination values of the compression behavior variable are determined therefrom. This creates an association between the individual test values of the state variable (that is to say for example different dynamic pressures) and the determination values (for example different values for the compression module). This assignment can be used within the framework of the criterion to determine what the lowest or highest value of the state variable is (that is, for example, the lowest dynamic pressure) at which the gas
    is still in solution.
    7739
    When inferring the lowest or highest value of the state variable at which the gas in the molding compound is in solution, one of the test values can be used for the state variable. In principle, interpolation could also be made between the test values or other methods could be used to obtain intermediate values
    between the test values.
    When checking the criterion, the determination values and, if necessary, the test values are used to infer a state of solution of the gas in the molding compound. The criterion can in particular take into account the behavior of the compression behavior variable for different test values of the state variable (that is to say, for example, the behavior of the compression module in
    different back pressures).
    The criterion can preferably be aimed at the complete dissolution of the gas in the molding compound. In certain situations, however, it can be sufficient if a small part of the gas is not in solution (for example if the absolute or
    relative amount of the undissolved gas does not exceed a limit value).
    In the simplest case, i.e. For example, if the mixture of molding compound and gas is known very precisely, the criterion can be a limit value for the compression behavior variable. The lowest test value of the state variable whose (determination value of the) compression behavior variable meets the limit value,
    could then be used as a target value.
    In other cases, criteria can be used which describe a behavior of the compression behavior variable across the various test values of the state variable. Specific examples of such criteria are given below
    specified. It can preferably be provided if for the implementation of the
    Method according to the invention for determining the target value for the state variable
    a single machine is used. It can particularly preferably be provided
    that this machine is also the machine that is used to carry out the
    Molding process is provided.
    For example, the plasticizing unit (also referred to as an injection unit) of an injection molding machine can be used to determine the target value for the dynamic pressure, provide the mixture of plastic and gas below the target value for the dynamic pressure for carrying out the molding process, and into the Shape of a molding tool mounted on the clamping unit of the injection molding machine
    inject.
    As an alternative to the use of an injection unit, one can be stored in a buffer
    (Engl .: "shot pot") stored plastic melt can be used.
    In particular, essentially the same mixture can be used to provide the mixtures with different test values of the state variable, i. E. essentially the same molding compound and essentially the same gas, preferably essentially in the same mixing ratio, can be used. Deviations can of course result from the measurement accuracy, the accuracy of the control of various machine components or from
    Result in batch fluctuations.
    It can preferably be provided that the method according to the invention is carried out on mixtures provided one after the other, preferably using the same machine. Theoretically, it would of course also be conceivable to provide the mixtures on different machines and to carry out the method according to the invention distributed on different machines. In other words, there is no pre-determined sequence of procedures beyond those that are
    results from logic.
    An example of a preferred time sequence could look like this. (i) a first test value for the state variable is selected, (ii) a mixture of the molding compound and the gas is provided,
    (ii) the mixture is compressed or decompressed at least once,
    (iv) during compression or decompression, the state variable and / or the at least one further state variable of the mixture is measured,
    (v) a first determination value of the compression behavior variable characteristic of the compression behavior of the mixture is determined from measured values of the state variable and / or the at least one further state variable,
    (vi) a second test value for the state variable that deviates from the first test value is selected and steps (ii) to (v) are repeated with the second test value, so that a second determination value of the compression behavior variable characteristic of the compression behavior of the mixture is available,
    (vil) with the selection of further test values that differ from the first and second dynamic pressure values, steps (ii) to (v) are repeated so that further determination values of the compression behavior variable characteristic of the compression behavior of the mixture are available,
    (vili) after each implementation or at the end of the method, the criterion and, based on the result (s), the target value for the state variable
    certainly.
    The compression behavior variable can of course also describe the behavior of the mixture during decompression, if this is necessary for certain materials
    Difference.
    The compression or decompression of the mixture for a test value of the state variable as well as the measurement of the state variable and / or the further state variable (that is, for example, the above steps (iii) and (iv)) can be carried out several times. The determination values for the compression behavior variable determined from these measured values can be averaged, for example within the scope of a mean value formation or median formation, in order to allow the process to settle
    enable and increase the measurement accuracy of the determination values.
    With these repetitions, further parameters, such as an adaptation of a metering rate, can also be carried out, for example in
    lower pressures to achieve the same dosing time.
    In the case of a version with a plasticizing screw, a rotation speed of the screw (which is the circumferential speed of the
    Snail determined).
    With a lower back pressure, the same (or similar) plasticizing performance can be achieved on the mixture even with a more slowly rotating plasticizing screw, whereby the dosing time is reduced even with a lower back pressure
    does not have to extend.
    The dosing time can be understood as the time to get the (desired amount of)
    Provide mixture.
    Advantageous further developments of the inventions are in the dependent claims
    Are defined.
    That the state variable for which the target value is to be determined is a dynamic pressure
    can, has already been mentioned.
    In such an embodiment, the method according to the invention can take the following steps
    include:
    - Mixtures of the molding compound and the gas under different dynamic pressures are provided,
    - the mixtures under the different dynamic pressures are each compressed or decompressed at least once,
    - During the compression or decompression, the dynamic pressure and / or the at least one further state variable of the mixture is either directly or
    measured indirectly,
    - from measured values of the dynamic pressure and / or the at least one further state variable, determination values of a compression behavior variable characteristic of the compression behavior of the mixtures are determined, and
    - A criterion directed to a state of solution of the gas in the molding compound is checked, as a result of which, on the basis of the back pressure and the determination values, a lowest back pressure at which the gas in the molding compound is in solution and this lowest back pressure at which the gas is in the molding compound is in solution is used as the target value of the back pressure to be determined
    used.
    With the method according to the invention, however, a target value for a temperature of the mixture of the molding compound and the gas could also be determined, since the gas will precipitate (or not go into solution) even if the temperature is too low
    the molding compound can happen.
    When compressing or decompressing the mixtures, the test values of the state variable can be specified in a controlled or regulated manner and / or can be measured. In other words, control values for actuators and other controllable elements (for example heating elements) which arise when the mixture is provided by a machine can be used as test values. Of course, measured values can also be used as test values, which are measured, for example, in the context of regulating the actuators or the other controllable elements. There are also combinations of measured values and control values
    usable.
    From the measured values of the state variable and / or the at least one further state variable when compressing or decompressing the mixture, a change in pressure, in particular an increase in pressure, and / or a change in volume, in particular a reduction in volume, of the mixtures can be calculated and the results of this calculation for determination (in particular calculation ) the determination values of the compression behavior variable are used
    will.
    In other words, for the measurement of the compression behavior variable for
    Obtaining the measured values sensors, in particular pressure sensors, can be used.
    In the specific example of a plasticizing unit for an injection molding machine, which is equipped with a plasticizing screw (hereinafter also referred to as "screw" for short) arranged in a plasticizing cylinder, the change in pressure and / or the change in volume can be caused by a force that drives the plasticizing screw via the Plasticizing screw exerts on the mixture, and / or a travel of the screw can be detected. Both control values for the drive and measured values can be used for this purpose (for example, predetermined or measured hydraulic pressures or drive torques of an electric drive). The change in volume and pressure change can be determined from the travel distance and the
    Calculate the known cross-sectional area of the plasticizing cylinder.
    During the injection of the plastic melt, the force or
    the pressure recorded in this way is referred to as the injection force or the injection pressure.
    A compression modulus and / or a compressibility of the mixtures can be used as the compression behavior variable, the determination values of which are determined
    will.
    Other compression behavior variables are also conceivable. For example, if the change in volume or the change in pressure (relative or absolute) is known, the change in pressure or the change in volume could also be called
    Compression behavior variable can be used.
    For example, the volume could also be kept constant, with the compression or decompression by adding or removing a certain amount
    Amount of substance of the mixture would have to happen. The criterion can be specified in such a way that when determining the lowest or highest value of the state variable, at least two of the determination values
    be taken into account. All determination values and test values up to
    At a certain point in time (during the implementation of the method according to the invention or at the end), can be used for the criterion. This enables the behavior of the
    Compression behavior variable to be taken into account via the various test values.
    In particular, the criterion could be specified in such a way that a curve fit is carried out on pairs of values of determination values and test values on a specified curve type, a fit curve being obtained from the curve fit and the specified curve type preferably being a straight line. Alternatively, other types of curves can also be used that determine the behavior of the compression behavior variable
    Describe (possibly better) about the various test values.
    For example, when closing to the lowest or highest value, the
    State variable in which the gas is in solution, can be inferred from a specific one of the test values, in which the respective determination value and / or the respective test value is at least by a predetermined absolute or relative amount from the
    Fit curve deviates.
    Providing the mixtures, compressing or decompressing the mixtures and measuring the at least one state variable, and preferably
    the determination of the determination values can be carried out one after the other.
    It can be particularly advantageous if the criterion is checked after each determination of one of the determination values. As soon as the criterion is met, the method can namely be ended, which means that it is carried out particularly quickly
    of the procedure.
    When the mixtures are provided successively, successively higher
    or lower test values are used for the determination values.
    It should be noted that the introduction of the gas into the molding compound and / or the
    Chamber can happen during a plasticizing process. The introduction of the
    Gas into the molding compound can be injected, in particular by means of a gas injector,
    be performed.
    The method according to the invention can be carried out partially or fully automatically, for which in particular the machine control unit of the molding machine
    can be formed.
    If a plastic melt is used as the molding compound, the checking of the criterion directed to the state of the solution of the gas in the molding compound could also be referred to as the determination of the state of solution in the plastic melt
    will.
    A pressure, also referred to as dynamic pressure, can be used as the state variable
    Plastic melt can be used.
    Providing the mixtures, i. the molding compound together with the gas
    done in a chamber.
    Compressing or decompressing the mixture can then be done by changing the volume of the chamber, the pressure (i.e. the dynamic pressure) in the chamber changing from a first pressure value to a second pressure value,
    especially increased.
    The plastic melt can then be introduced into a molding cavity.
    The determination values of the compression behavior variable can then also be referred to as “at least one compression parameter characteristic of the compression behavior of the plastic melt”, which can in particular be the compression module, and it can be derived from the first
    Pressure value and the second pressure value are calculated.
    The mentioned checking of the criterion can be realized in that
    it is determined from the determination values of the compression behavior variable whether the
    Gas is essentially completely dissolved in the plastic melt, and / or a solubility limit of the from the determination values of the compression behavior variable
    Gas in the plastic melt is determined.
    Inferring the lowest or highest value of the state variable at which the gas in the molding compound is in solution, and using it as a target value to be determined for the state variable, can then also be used to minimize the pressure / dynamic pressure
    are designated.
    Analog can be used to minimize the temperature of the plastic melt instead of the
    Back pressure are proceeded.
    The minimization of the dynamic pressure or the temperature is in this case as a reduction of the dynamic pressure or temperature, so that the essentially complete dissolution of the gas in the plastic melt can still be expected
    understand.
    The solution state, i.e. the question of whether or to what extent the gas is completely dissolved in the plastic melt can be determined from the at least one compression parameter if the relationship between the at least one compression parameter and the state of solution is known. In the context of the invention, the determination of the solution state is considered to be a determination of whether the gas is essentially
    is completely dissolved in the plastic melt.
    The solubility limit is an amount of gas above which there is no longer a complete solution of the gas in the plastic melt. The solubility limit can depend on further parameters, such as the materials used and the temperature. It can be formulated as an intense or extensive quantity
    will. For the calculation of the determination values of the compression behavior variable, in particular the compression modulus, in addition to a pressure change for
    data relating to volume change are usually also used.
    As already mentioned, it can be provided that an injection unit with a plasticizing screw arranged in a plasticizing cylinder is used, the plasticizing screw being moved in rotation for plasticizing the plastic and being moved axially for injection. Of course, the accumulation of plastic melt in the screw antechamber can result in an axial movement of the plasticizing screw during plasticizing. A rotating movement during the injection is also possible. In most cases, injection molding machines have injection units with plasticizing cylinders and plasticizing screws, so that no major structural changes are made in this advantageous version
    must be in order to implement the method according to the invention.
    Similar advantages with regard to a simple implementation of the method according to the invention can result from the use of a screw antechamber in one
    Plasticizing cylinder as a chamber in which the mixtures are provided.
    In preferred embodiments, the chamber may also be conducive to a simple process configuration that the chamber is delimited on the mold cavity side by a shut-off device, preferably in the form of a needle valve nozzle, and / or that the chamber is on its side facing away from the mold cavity
    is limited by a plasticizing screw or an injection piston.
    Alternatively, a separate chamber can be used for providing the mixtures, which chamber is limited, for example, by one or more shut-off devices
    becomes.
    It can be provided that the compression or decompression of the mixtures is carried out as part of an injection process. For example, a feed of a plasticizing screw for injection can be used in an injection molding process to compress the mixtures. This saves time because the mixtures are not compressed separately
    must become.
    However, the invention can also be used without injecting the mixture after each
    Compress or decompress can be done.
    As already mentioned, with different test values of the state variable, the mixtures can be implemented by one and the same mixture, in which only the state variable is changed, or new mixtures are provided for each test value. In the latter case, the mixing ratios between the molding compound and the gas (i.e. in particular the concentration of the gas in the molding compound) are essentially, i.e. in the context of the control and / or
    Measurement accuracy, same.
    In a particularly simple embodiment, a change in volume of the chamber can be determined by determining a
    Plasticizing screw path can be carried out.
    It can particularly preferably be provided that the test values for the state variable - in particular the dynamic pressures - are selected at least partially so high that complete dissolution of the gas in the molding compound can be expected. In particular, if the test values are successively reduced from a high, experience-based starting value (e.g. 200 bar), this can make it possible to approximate an optimized target value of the state variable from a range
    takes place in which the solution of the gas in the molding compound is secured.
    The test values can be set at a constant interval (of for example 20 bar)
    be chosen from each other.
    While the method according to the invention is being carried out for determining the setpoint value for the state variable, other state variables can be controlled or regulated - preferably in such a way that they remain constant. For example, in the case of dynamic pressure as a state variable, the temperature of the mixture can be constantly regulated as another state variable (or vice versa) in order to make the
    to ensure individual determination values.
    After compressing or decompressing, the melt can be left unchanged for a period of time (for example with a constantly regulated state variable and / or other state variables) so that a thermal
    Equilibrium sets.
    The determination of the determination values of the compression behavior variable, in particular the compression module, can take place in an automated manner. In particular, for example, after the start of a program for detecting the compression module
    a delay in the opening of the shut-off nozzle can be activated.
    Then, for example, a change in volume AV and a change in pressure Ap can be automatically determined by the molding machine via the machine-internal process data acquisition system. Thereafter, for example, the compression modulus K can be automatically determined, saved and stored after each shot using the equation K = V) Ap / AV (with Vo being the volume before compression)
    may be issued.
    By realizing the points described here - in particular the automated implementation - many decisions can be relieved of the operator and production can be significantly simplified and made more economical. Automation also enables the operator to use manual
    Implementation are accepted.
    Injecting gas and introducing gas are understood to mean the same thing, i.e. this
    Terms are used interchangeably.
    Further advantages and details of the invention are evident from the figures and FIG
    associated figure description visible. Show it:
    1 shows a diagram to illustrate the solubility limit of a mixture of a molding compound and a gas,
    Fig. 2 shows an embodiment of an injection molding machine for implementation
    a method according to the invention,
    3a to 3c are diagrams to illustrate the dependence of the solubility limit on the dynamic pressure, and FIGS. 4a to 4f are diagrams to illustrate the invention
    Procedure.
    1 shows a diagram in which the compression modulus K of a mixture 1 of a molding compound - in particular a plasticized thermoplastic - is plotted against the amount of gas loading. A characteristic strong drop in the compression module K from a certain gas load can be seen. The beginning of the waste, which is marked by a vertical line, indicates the point from which the amount of gas in the plastic is so great that the entire amount of gas in the plastic is no longer in solution, but instead precipitates as bubbles and therefore as second phase is present. This point marked with the vertical line is called
    Called solubility limit.
    A fundamental aspect of the present invention is that the exact position of the solubility limit depends on the thermodynamic state of the mixture 1 of molding compound
    and gas depends.
    For a shaping process in which the mixture 1 is to be used, this means that the state variables which describe the thermodynamic state of the mixture 1 must lie within a certain range. Otherwise the gas in the molding compound is not in solution, which is the
    The shaping process is negatively affected.
    Before embodiments of the method according to the invention are explained, there follows a description of a device / machine preferably used to carry out a method according to the invention, namely a shaping machine
    2 in the form of an injection molding machine, which is shown schematically in FIG.
    In Fig. 2 a molding machine 2 - in this case an injection molding machine -
    shown. It has an injection unit 10 for producing a
    Plastic melt by plasticizing a plastic (usually as granules
    present).
    For this plasticizing, a plasticizing screw 8 is arranged in a plasticizing cylinder. By rotating the plasticizing screw 8 (shear heat) and heating the plasticizing cylinder, the plastic is melted and is then present as plastic melt in the screw antechamber in the plasticizing cylinder. This process
    the production of the plastic melt is also referred to as "dosing".
    The plasticizing screw 8 can also be moved axially. In particular, the plastic melt can not be separated by advancing the plasticizing screw 8 into one
    Shaping cavity shown are injected.
    In addition, there is a closing unit 6 which, via two clamping plates, has a closing force on a mold to be mounted thereon for holding (also referred to as mold clamping) the mold. In the closed state shown, the molding cavity is created by the molding tool in its interior
    educated.
    The drive 5 for the rotating and axial movement of the
    Plasticizing screw 8 and a machine control 3 are shown.
    A gas injector 9 is provided for introducing the gas into the plastic melt.
    In this exemplary embodiment, the gas injector 9 is overlapping with a mixing part
    the plasticizing screw 8 is arranged.
    By injecting the gas into the plastic melt, the screw antechamber
    (Chamber) the mixture 1 made of the molding compound and the gas. Between the plasticizing cylinder and the molding cavity is a shut-off device 7, which can be designed as a needle shut-off nozzle, for example
    can, arranged.
    21739
    The shut-off device 7 is used to shut off the flow of the plastic melt into the molding cavity. As a result, the antechamber can form a closed chamber in which the mixture 1 can be enclosed. By axial movement of the plasticizing screw 8, the volume of the so formed
    Chamber changeable.
    Two sensors 4, which are provided for detecting the force exerted on the mixture 1 and the axial position (travel distance) of the plasticizing screw 8, are shown schematically. The sensor 4 for detecting the force could, for example, measure a hydraulic pressure in a hydraulic cylinder driving the screw feed (as part of the drive 5) or a torque of an electrical machine driving the screw feed (as part of the drive 5). Through the sensors 4, the dynamic pressure MPP and (via the known geometry of the plasticizing cylinder and the plasticizing screw 8) the volume of the im
    Mixture 1 present in antechamber can be measured.
    Of course, for example, the dynamic pressure MPP could also be directly via a
    Pressure sensor can be measured at the screw antechamber.
    The name MPP comes from the abbreviation for "MuCell Process Pressure" for the back pressure in the MuCell process.
    The machine control device 3 is signal-connected to the drive 5 of the plasticizing screw 8 and the sensors 4. The machine control device can be arranged directly on the machine or via
    a data transmission link can be arranged remotely from the machine.
    The following is the compression or decompression of the mixture 1 using the injection molding machine shown in FIG. 2 as well as the determination of a determination value of the compression behavior variable (here: compression module K)
    described.
    After this dosing, the gas-laden plastic melt stands, i.e. the mixture under dynamic pressure MPP, the value of the dynamic pressure MPP being one of the test values. The compression process is then initiated by the advance of the plasticizing screw 8, the shut-off device 7 initially remaining closed. The screw feed is continued with pressure control until a predetermined increased pressure is reached. The increased pressure can be a value of the test value of the dynamic pressure MPP that is increased by a predetermined pressure difference Ap.
    The predetermined pressure difference Ap can be 400 bar, for example.
    By detecting the path (screw path) covered by the plasticizing screw 8 from a value that corresponds to the volume of the mixture 1 before the reduction to a further value that corresponds to the volume of the mixture 1 after the reduction, the change in volume AV can be recorded . The increased pressure can be maintained over a period of time in order to ensure that a state of equilibrium has occurred. The further value of the
    The snail's path is then of course recorded according to the period.
    As mentioned, the volume change AV and the pressure difference Ap can be recorded from the recorded screw path via the known diameter of the plasticizing cylinder 6. In a similar manner, an initial volume Vo of the mixture 1 can be determined before the compression of the mixture 1 begins. The compression modulus K (i.e. one of the determination values for
    Compression behavior quantity), defined as - _y AP K = Vor)
    be calculated.
    The shut-off device 7 could then be opened and the process of injecting the mixture 1 into the cavity could be continued. Alternatively, the mixture 1 can be kept in the plasticizing cylinder in order to provide a further determination value of the compression behavior variable with a further test value of the dynamic pressure MPP
    to capture.
    To understand the method according to the invention, FIGS. 3a, 3b and 3c show the determination values of the compression modulus K for three different gases (FIGS. 3a and 3b: molecular nitrogen, FIG. 3c: carbon dioxide) with a fixed gas concentration (FIG. 3a: 1, 2%, Fig. 3b: 0.6%, Fig. 3c: 3.5%) over the test values of the dynamic pressure MPP
    applied.
    These figures also show a characteristic drop in the compression modulus K when the dynamic pressure MPP falls. The aim of the method described below is to find a target value for the dynamic pressure that is as low as possible (in order to keep the energy expenditure for the process as low as possible) and which is at the same time so high that it will fail the gas loading (desorption of the gas from the molding compound) has no negative influence on the molding process. A corresponding procedure is provided in
    Described below in connection with FIGS. 4a to 4f.
    The exemplary embodiment starts with the determination of a first determination value of the compression module K for a first dynamic pressure MPP, which represents a first test value of the dynamic pressure state variable. This first test value and this first
    Determination values are shown in a diagram in FIG. 4a.
    The process is repeated so that a second determination value of the compression module K for a second dynamic pressure MPP (a second test value) is also available. This is shown in Fig. 4b. A fit curve in the form of a first best-fit straight line AG1 can be determined from the two pairs of values present,
    which is also shown in FIG.
    In a third step, a third determination value of the compression module K for
    a third dynamic pressure MPP determines what is shown in Fig. 4c.
    As a criterion directed to the state of solution of the gas in the molding compound, it is now checked whether a difference D3, which is a deviation of the third determination value from the best-fit straight line AG1 at the third dynamic pressure MPP,
    falls below a limit value.
    24/39
    In the present exemplary embodiment, the limit value is defined relative to the first best-fit straight line AG1, namely as 2% below the value of
    Best fit straight line AG1 at the second dynamic pressure MPP (second test value).
    I.e. it is checked within the framework of the criterion whether the third determination value is around
    is more than 2% below the regression line AG1 or not.
    This is not the case in FIG. 4c, which is why a second curve fit is performed using a further curve fit
    Best-fit straight line AG2 is determined, which is also shown in Fig. 4c.
    The procedure is repeated so that in FIG. 4d there is a fourth determination value of the compression module K at a fourth dynamic pressure MPP. The previously described criterion is checked again, the check being negative again because the difference D4 is less than 2% of the value of the best-fit straight line AG2. As a result, a third best-fit straight line AG3 becomes the one existing up to this point in time
    Determination values and test values fitted.
    The criterion is also not met in FIG. 4e because the fifth determination value for the dynamic pressure MPP is not more than 2% below the best-fit straight line AG3. The regression line AG4 is fitted.
    In the next step in Fig. 4f this is already the case, i.e. the difference D6 between the sixth determination value of the compression module K and the best-fit straight line AG4
    is greater than 2% of the value of the best-fit straight line AG4.
    From this it can be concluded that the gas at the sixth dynamic pressure MPP (i.e.
    at the sixth test value) is no longer completely dissolved in the molding compound.
    Therefore, the fifth dynamic pressure MPP (fifth test value) is selected as the target value for the dynamic pressure MPP in the molding process to be carried out because this is the lowest test value for the dynamic pressure MPP at which a complete solution of the
    Gas in the molding compound is to be assumed.
    At this point, an attempt could be made to interpolate between the sixth test value and the fifth test value in order to optimize the dynamic pressure even further. With the density of the test values for the dynamic pressure selected here, this must be
    but not be absolutely necessary.
    A particularly preferred, more detailed exemplary embodiment based on the concept described above is given below. The implementation of individual compressions or decompressions and the respective measurement of the state variable or the further state variable, possibly together with a shaping process,
    are referred to here as "shots".
    Process sequence of a preferred embodiment: 1. Check feasibility: Dosing speed should not be more than half of the possible (later increase may be necessary) 2. Set back pressure to 200 bar, for example, activate injector Explanation: 200 bar is very high, therefore guarantees the solution industrially used gas container. Note: The actual back pressure can be made dependent on the pre-selection of material and gas content, i.e. it can therefore also be below 200 bar. Stored guide values can be used for this. From here on, the counting is in loops 1. 10 shots (if the MPP is only changed in subsequent loops, 5 shots can be sufficient) without changing any other settings (settling, gas enrichment). 2. Iterative adjustment (increase / decrease) of the dosing speed in order to maintain the dosing time (ideally: new dosing time = compact dosing time; criterion: time is within 5% of a target dosing time) 3. Another 5 shots after the adjusted dosing time (Process stabilization; time
    should not move out of the 5% range around the target dosing time)
    4. Measurement of the compression modulus with 10 subsequent shots - averaging
    5. Comparison of the measurement with the extrapolated value of the previous loop at the same pressure (from 3rd loop)
    6. Lowering the MPP by 10 bar
    7. Calculation of a best-fit straight line using previous measured values (from the 2nd loop)
    8. Repeat steps 3-8 as long as the K-module is less than 1% below the extrapolated best-fit straight line (check the criterion only from the 3rd loop)
    9. The last MPP before this outlier corresponds to the minimum required MPP
    As already mentioned, this method can also be used analogously with a temperature of mixture 1 as the one to be optimized (i.e. to be minimized or maximized)
    State variable can be carried out.
    This design can be implemented fully automatically in a central machine (control) control unit of a molding machine, in particular an injection molding machine. The operator then only has to find the desired gas content in the mixture
    pretend.
    Innsbruck, October 7, 2019
    27739
    权利要求:
    Claims (1)
    [1]
    Claims
    Method for determining a setpoint value of a state variable - in particular a dynamic pressure (MPP) - of a mixture (1) intended for a molding process and composed of a molding compound and a gas, wherein
    - the mixture (1) of the molding compound and the gas is provided with different test values of the state variable,
    - the mixture (1) present for the different test values of the state variable is in each case compressed or decompressed at least once,
    - during compression or decompression, at least the state variable of the mixture (1) and / or at least one further state variable of the mixture (1) is measured directly or indirectly,
    - determination values of a compression behavior variable characteristic of the compression behavior of the mixture (1) are determined from measured values of the state variable and / or the at least one further state variable, and
    - A criterion directed to a state of solution of the gas in the molding compound is checked, as a result of which, based on the test values and the determination values, a lowest or highest value of the state variable at which the gas is in solution in the molding compound and this lowest or highest value is inferred the state variable at which the gas in the molding compound is in solution, as the target value to be determined
    the state variable is used.
    Method according to Claim 1, characterized in that the state variable is a dynamic pressure (MPP) of the mixture.
    Method according to one of the preceding claims, characterized in that
    that the state variable is a temperature of the mixture.
    Method according to one of the preceding claims, characterized in that
    that the test values of the state variable when compressing or decompressing
    86642 32 / as 2
    the mixture (1) can be controlled or regulated and / or measured
    will.
    Method according to one of the preceding claims, characterized in that a pressure change (Ap), in particular an increase in pressure, and / or a volume change (AV), in particular volume reduction, of the mixture (1) is derived from the measured values of the state variable and / or the at least one further state variable ) calculated and used to determine the
    Determination values are used.
    Method according to one of the preceding claims, characterized in that a compression modulus (K) and / or a compressibility of the mixture are used as the compression behavior variable, the determination values of which are determined
    (1) is used.
    Method according to one of the preceding claims, characterized in that the criterion is specified in such a way that, when determining the lowest or highest value of the state variable, at least two of the determination values
    be taken into account.
    Method according to Claim 7, characterized in that the criterion is specified in such a way that a curve fit is carried out on pairs of values of determination values and test values on a specified curve type, a fit curve (AG1, AG2, AG3, AG4) being obtained from the curve fit and the given
    Curve type is preferably a straight line.
    The method according to claim 8, characterized in that when inferring the lowest or highest value of the state variable at which the gas is in solution, a certain one of the test values is deduced at which the respective determination value and / or the respective test value is at least one specified absolute or relative amount (D3, D4, D5, D6) from the fit curve
    deviates.
    Method according to one of the preceding claims, characterized in that
    that the provision of the mixture (1) at different test values of the
    12.
    13.
    86642 32 / as 3
    State variable, compressing or decompressing the mixture (1) and measuring the at least one state variable and preferably that
    Determination of the determination values are carried out one after the other.
    The method according to claim 10, characterized in that the criterion according to
    each determination of one of the determination values is checked.
    A method according to claim 10 or 11, characterized in that when the mixture (1) is provided successively, successively higher or
    lower test values can be used for the state variable.
    Method according to one of the preceding claims, characterized in that
    that
    - a plastic melt is used as molding compound,
    - a dynamic pressure (MPP) or a temperature of the plastic melt is used as the state variable,
    - the review of the criterion directed to the state of the gas in the molding compound as the determination of the state of the solution in the plastic melt is implemented,
    - the mixture (1), i.e. the molding compound is provided together with the gas in a chamber,
    - The compression or decompression of the mixture (1) is realized by changing the volume of the chamber, the dynamic pressure (MPP) in the chamber changing, in particular increasing, from a first pressure value to a second pressure value,
    - the plastic melt is introduced into a molding cavity,
    - the determination values of the compression behavior variable are calculated from the first pressure value and the second pressure value,
    - it is determined from the determination values of the compression behavior variable whether the gas in the plastic melt is essentially completely dissolved and / or from the determination values of the compression behavior variable a solubility limit of the gas in the plastic melt is determined,
    and or
    15th
    16.
    17th
    86642 32 / as 4
    - The inference to the lowest or highest value of the state variable at which the gas in the molding compound is in solution, and the use as a target value to be determined for the state variable is realized by minimizing the dynamic pressure (MPP).
    Shaping method, wherein a method according to one of the preceding claims is carried out and the target value of the state variable as
    predetermined target value is used for the shaping process.
    Molding machine with a machine control unit (3), which is set up to the molding machine (2) for performing a method
    according to one of claims 1 to 13.
    Molding machine according to claim 15, characterized in that the machine control unit (3) is designed to perform the method according to one of the
    Perform claims 1 to 13 partially or fully automated.
    Computer program product - in particular for performing a method according to one of claims 1 to 13 - for determining a setpoint value of a state variable of a mixture (1) of a molding compound and a gas intended for a molding process, including commands that cause an executing computer (3) to do so ,
    - to control at least one device (2) in such a way that the mixture (1) of the molding compound and the gas present with different test values of the state variable is provided
    - to control the device (2) in such a way that the mixture (1) present for the different test values of the state variable is compressed or decompressed at least once,
    - To receive measured values of at least one sensor (4), which at least one sensor (4) when compressing or decompressing the mixture (1) the state variable and / or at least one further
    Measures the state variable directly or indirectly,
    to determine from the measured values determination values of a compression behavior variable characteristic of a compression behavior of the mixture, and
    - to check a criterion directed to a solution state of the gas in the molding compound, whereby based on the test values and the determination values, a lowest or highest value of the state variable at which the gas is in solution in the molding compound, and this lowest back pressure, is concluded where the gas is in solution,
    output as dynamic pressure to be determined.
    Innsbruck, October 7, 2019
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    同族专利:
    公开号 | 公开日
    US20190329470A1|2019-10-31|
    CN110394956B|2022-02-22|
    AT520733B1|2019-07-15|
    DE102019108997A1|2019-10-31|
    CN110394956A|2019-11-01|
    AT520733A4|2019-07-15|
    KR20190124652A|2019-11-05|
    KR102246701B1|2021-05-03|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50349/2018A|AT520733B1|2018-04-25|2018-04-25|Method for determining a solution state of a gas|DE102020109381.0A| DE102020109381A1|2019-04-05|2020-04-03|Method for determining a desired value of a state variable|
    US16/839,419| US20200316838A1|2019-04-05|2020-04-03|Method for determining a target value of a state variable|
    CN202010259887.1A| CN111791445B|2019-04-05|2020-04-03|Method for determining a target value for a state variable of a mixture|
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