• 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:
    Energy supply device for a molding machine with 75755 32 / fr - a DC link (2) which is connectable to at least one drive (3) of the forming machine, a power grid (4) and an energy store (5), - a measuring device (6) for measuring a electrical voltage (UzK) or an electric current at the intermediate circuit (2) and - a control device (7), by means of which an energy transfer between the power supply network (4) and the intermediate circuit (2) in dependence of the measured voltage (UzK) or the measured current is controllable, wherein the control device (7) is adapted to increase the power supply network (4) provided at the intermediate circuit (2) network power (PN) in terms of amount, if the measured voltage (UzK) or the measured current leaves a first range, and to reduce the network power in amount, if the measured voltage (UzK) or the measured current enters a second area, wherein the second area is smaller than the first area and is completely contained in the first area.
    公开号:AT515985A1
    申请号:T539/2014
    申请日:2014-07-07
    公开日:2016-01-15
    发明作者:
    申请人:Engel Austria Gmbh;
    IPC主号:
    专利说明:

    The present invention relates to a power supply apparatus for a molding machine having the features of the preamble of claim 1 and a method of energizing a molding machine having the features of the preamble of claim 16.
    By molding machines can be understood injection molding machines, transfer molding, pressing and the like.
    It is known to provide electrical axle movements by a utility (= power delivery) via DC bus to provide the power. This is done by rectifying the mains input voltage and additionally increasing it by 35% to the rectification value. In the power converter, this DC voltage is changed back into a rotating field to drive the motor with it. The design of this rotating field, the speed and the power of the motor can be controlled. With regenerative systems, it is also possible to reverse the energy flow in order to bring energy stored in the mechanical system back into the network in the same way.
    For example, in high-performance injection molding machines, the ratio of peak to nominal power is up to 4: 1.
    Since the power output stages must be designed for the maximum power to be provided, this ratio requires the use of large output stages, which are then underutilized. This situation drives up the cost of the drive systems.
    Since the overload must be provided exclusively by the network, high peak power tariffs are charged by the network operator.
    In summary, the following drawbacks occur with prior art power supply devices: I. Large supply devices II. Large losses III. High costs IV. Poor utilization V. High excellence VI. Large reactive power requirement
    The object of the invention is to provide a power supply apparatus for a molding machine and a method for powering a molding machine, wherein the capacity of the power storage is reduced or the occurrence of power peak power is reduced.
    This object is achieved with regard to the device by the features of claim 1 and with respect to the method with the features of claim 16.
    This is done by: determining a first region and a second region for the voltage measured at the intermediate circuit or the current measured at the intermediate circuit, the second region being smaller than the first region and being completely contained in the first region, and a power supply provided by the energy supply network at a DC link is increased in magnitude if the measured voltage or the measured current leaves the first range and the network power is reduced in magnitude if the measured voltage or the measured current enters the second range.
    The first and second ranges may each be given by the values above or below a threshold or threshold. Likewise, the ranges may be given by values between two limit or threshold values. Of course, even more complex value ranges are conceivable.
    By the term "increased in value", it can be understood that negative network performance is reduced and positive network performance is increased.
    As a criterion that the second area is smaller than the first area and is completely contained in the first area, it may be used to give values that are part of the first area but not part of the second area and that there are no values that are part of the first area second area, but not part of the first area.
    It should be noted that the control device of the power supply device according to the invention does not have to regulate a voltage present at the intermediate circuit or a current occurring at the intermediate circuit in such a way that the measured voltage or the measured current is regulated to a desired value. Rather, regulation is here taken to mean, in a somewhat broader sense, that the measured voltage or current is kept within an acceptable range. Of course, it is still possible to additionally control or regulate a parameter - for example the voltage or the current - of the intermediate circuit.
    Unless explicitly stated otherwise, the word "or" is to be understood inclusive for the purposes of this patent, i. also the application of the two by "or" separate options is possible.
    The invention makes it possible to use smaller supply systems designed for a ratio of less than 2: 1 from peak to nominal power. This allows a very good utilization during operation. In order to meet the technically still existing need for peak power this is provided via an integrated electrical energy storage. However, this memory is limited in its size and energy providing capability and therefore less expensive because the size and layout of the energy storage have a large impact on the manufacturing cost of the energy storage. Much of the machinery is not in the
    Peak power range operated. By the invention it can be avoided to tune the design of the energy storage to the peak power range, as was still necessary in the prior art. A reduction and associated cost savings are made possible by the invention.
    In the meaning of the invention, therefore, the additional energy demand to be provided by the energy storage device can be calculated on the basis of an average power profile. Nonetheless, the shaping machine according to the invention ensures perfect functioning, since even peak powers which the energy store can no longer compensate are compensated by additional power of the power supply network.
    One aspect of the invention is the recognition that a large increase in the motor or generator power of the at least one drive can be detected via the voltage measured at the intermediate circuit or the current measured at the intermediate circuit.
    This also applies to a subsequent stabilization of the performance of the at least one drive. The proposed control achieves a hysteresis effect, i. it prevents the network peak power from being immediately limited after the release of the power peak power (switching between enabled and disabled power peak power would be the consequence). This presence of a situation-dependent period of time before a reduced power is taken from the power supply network (or is supplied to it), allows the system of DC link, at least one drive of the forming machine and energy storage to get back into a stable state.
    Further advantageous embodiments of the invention are defined in the dependent claims of the invention.
    It can be preferred that the control device is designed to increase a grid power provided by the power supply network at the intermediate circuit if the measured voltage or the measured current falls below a lower limit and to reduce the grid power if the measured voltage or the measured current is a lower one Threshold, where the lower threshold is greater than the lower threshold. In this case, it should be noted that if the measured voltage is a DC voltage. the measured current is a dc current, choosing a positive convention for the readings. In this embodiment, the first range is given by values which are greater than the lower limit. The second range in this case is given by values greater than the lower threshold.
    In the case of energy supply devices which provide for a return of electrical energy to the energy supply network, it can also be preferred that the control device is designed to increase a recovery power provided by the intermediate circuit in the energy supply network, if the measured voltage or the measured current exceeds an upper limit value, and to reduce the recovery energy, if the measured voltage or the measured current falls below an upper threshold, the upper threshold being greater than the upper threshold.
    In contrast to the grid power, the regenerative power is positively counted if power is supplied by the DC bus at the power grid. The grid power will therefore generally be the negative value of the regenerative power.
    In this embodiment, the first range is given by values below the lower limit and the second range by values below the lower threshold.
    Of course, a combination of these two embodiments is conceivable. In this case, the first range is formed by the values between the lower limit and the upper limit. The second range includes the values between the lower threshold and the upper threshold.
    A particularly simple embodiment of the invention can be achieved by virtue of the fact that the intermediate circuit has an intermediate-circuit capacitor, which is preferably connected in parallel.
    In particular, when the intermediate circuit has an intermediate circuit capacitor, it can preferably be provided that the measuring device is designed as a voltage measuring device and the measured voltage or the measured current is an intermediate circuit voltage applied to the intermediate circuit, wherein the intermediate circuit voltage is preferably an electrical voltage applied to the intermediate circuit capacitor. For a quick return to a stable situation in the intermediate circuit, it can be provided that the control device is designed to increase the network power in terms of amount to a maximum network power if the measured voltage or the measured current leaves the first range.
    In order to prevent the occurrence of expensive power peaks even during stable operation, provision can be made for the control device to be designed to limit the network power to a fixed multiple, preferably 1.1 times, of a nominal power of the power supply network, if the measured voltage or the power supply voltage measured current enters the second area.
    Protection is also desired for a molding machine with an energy supply device according to the invention.
    The invention can preferably be used in energy stores with at least one storage capacitor for storing electrical energy. For these energy stores, a particularly large cost saving can be achieved by reducing the detection capacity.
    The energy store may be interpreted into the power supply device or provided separately.
    It is furthermore preferably provided that a capacity of the at least one storage capacitor is greater than a capacity of the intermediate-circuit capacitor. Most preferably, it may be that the capacity of the storage capacitor is greater by a factor of 10 to 30 than that of the intermediate circuit capacitor.
    Further advantages and details of the invention will become apparent from the figures and the accompanying description of the figures. Showing:
    1 shows a schematic circuit diagram of a power supply device according to the invention, connected to a power supply network, three drives of the shaping machine and an energy store,
    Figures 2a and 2b are diagrams and a flow chart for operation of a first embodiment of an energy supply device according to the invention as well
    3a and 3b are diagrams and a flowchart relating to a second embodiment of an inventive
    Power supply device.
    Figure 1 shows a power supply device 1 according to the invention in a schematic representation, which is filled in the connected to the driving 3 state for supplying the same with electrical energy. The power supply device 1 is connected to a plurality of drives 3 of the shaping machine, the power supply network 4 and the energy storage 5. The number of drives 3, which with the
    Power supply device are connected, is not essential to the invention. To connect the intermediate circuit 2 of the energy supply device 1, this has a power supply module 11, which is connected to the intermediate circuit 2. The power supply module 11 can furthermore be connected to the power supply network 4, the connected state being shown in FIG. Between the power supply network 4 and the power supply module 11, a physical switch 15 (main switch), a mains filter 16 and a mains choke 17 are connected.
    The power connection module 11 has a rectifier 12 for rectifying an AC voltage supplied by the power supply network 4. Also provided is an inverter 13, which can produce an AC voltage from the DC voltage in the intermediate circuit 2. This allows energy recovery from the DC link 2 to the power grid 4. Both rectifier 12 and inverter 13 are connected in parallel with the intermediate capacitor 8 of the DC link 2.
    The separation between rectifier 12 and inverter 13 is to simplify the schematic. In practical use, these elements are usually realized in a single component. (The regenerative power supply is therefore designed via one or more IGBTs).
    Also connected in parallel with the intermediate circuit capacitor 8 are the controlled or regulated power converters 14 for a plurality of drives 3 of the shaping machine. The power converters 14 convert the DC voltage drawn from the intermediate circuit 2 into an AC voltage for operating the drives 3. Finally, the energy storage 5 is connected in parallel with the intermediate circuit capacitor 8. The energy storage device 5 has at least one capacitor connected in parallel with the intermediate circuit capacitor 8 for storing electrical energy. Their total capacity is shown symbolically by a capacitor 9. The power supply device 1 furthermore has a voltage measuring device 6 for measuring the intermediate circuit voltage Uzk. The measured values of the voltage measuring device 6 are fed to the control device 7. On the basis of these measured values, the control device 7 regulates the rectifier 12 and the inverter 13. The operation of the control device 7 will be described below in connection with FIGS Figures 2a and 2b and 3a and 3b described.
    By the arrangement shown in Figure 1, it is possible to supply the drives 3 with electrical energy.
    Two diagrams are shown in Figure 2a, the first representing a hypothetical run of a link voltage Uz ", and the second representing a hypothetical run of the total power consumed by the drives 3 during one cycle, termed the PMotorcycle. As can be seen from the course of the two diagrams, breaks in this case by a high absorbed power of the drives 3, the intermediate circuit voltage Uzk.
    The procedure of the controller 7 in this case will now be described with reference to the flow chart of Fig. 2b. First, the controller 7 checks whether the intermediate circuit voltage Uzk is greater than a lower limit value Ufn. If this is the case, the grid power Pn is limited to 1.1 times the nominal power Pnenn. For clarity, the flowchart contains a visualization of a possible distribution of the total power between the network power PN and the power supply Ps provided by the energy store 5, following the flow chart. Then it is again checked whether the intermediate circuit voltage Uzk is greater than the lower limit value Ufn for the release of network peaks. If this is no longer the case, which occurs in the diagrams of Figure 2a at the time of the left vertical line, the maximum network power is enabled. This is illustrated in the flow chart by PNmax. Also in this case, a possible division between the maximum network power Pn.max and the memory power Ps is shown in order to achieve the complete system performance 2 provided to the drives 3. As can be seen, the ratio has shifted towards the power provided by the utility grid. As long as this maximum system power is allowed, it is checked according to the flowchart whether the intermediate circuit voltage Uzk is greater than the lower threshold value USn- If this is not already the case, the release of the maximum mains power Pn.max remains upright.
    If, however, the intermediate circuit voltage Uzk again reaches the lower threshold value Usn, which is the case in the diagrams from FIG. 2a at the time of the right vertical line, the grid power Pn is limited to 1.1 times the nominal power Pnenn of the power grid 4. According to the flow diagram of FIG. 2b, this is done first after a check as to whether the intermediate circuit voltage Uzk is greater than the lower limit Ufn-Da at which time the DC link voltage Uzk has already been greater than the lower threshold for blocking the network peaks and Usn is greater than UFn > this usually leads to the left arm of the flowchart.
    The time period Tf is the time between the release of network peaks and the subsequent limitation of the network peaks occurring in the hypothetical course of the intermediate circuit voltage Uz. As can be seen, this time difference Tp allows the system to return to a stable state.
    In the lower diagram of FIG. 2a, the course of the division between the power line Pn provided by the power supply network 4 and the power Ps produced by the power storage system can also be recognized. Until the release of the power spikes, the network power Pn remains below the level given by 1.1Pnens. The rest of the power is supplied by the energy storage.
    As soon as an exceptionally high power occurs, which occurs close to the sum of the maximum powers of the memory and the limited network power Pn (in the diagram referred to as 1.1 Pnenn + Ps.max) · the intermediate circuit voltage Uzk starts to break as the high power decrease extends over a longer period of time, The intermediate circuit voltage Uzk drops below the lower limit value Ufn for releasing the network tip, which triggers the above-described behavior of the control device 7.
    As will be further appreciated, in only a narrow range around the maximum total motor power PM.zykius.max achieved during a cycle, the expensive power peak power is used. This allows a relatively small dimensioning of the energy storage device 5 lead at the same time economical use of Netzspitze power.
    Furthermore, it can be seen in the lower diagram of FIG. 2a that the network power Pn briefly falls into the negative range. In this case, energy is fed back to the energy supply network 4 or the energy store 5 is charged.
    FIGS. 3 a and 3 b are analogous to FIGS. 2 a and 2 b, the first of which deals with the energy recovery to the energy supply network 4. While a hypothetical curve of the intermediate circuit voltage Uz "is again shown in the upper diagram of FIG. 3a, a power (referred to as a brake cycle) provided by the drives 3 on the intermediate circuit 2 is now shown in the lower area. This power is similarly divided into a regenerative power Pr and a charging power P | _, which are performed at the power supply network 4 and the energy storage 5 (for charging). Of course, the performances just mentioned correspond to the negative value of the analogous powers of Figures 2a and 2b. That is: P brake cycle ~ ^ motor cycle > Pr ~ ~ Pn > Pl ~ Ps
    In this case, due to the regenerative operation of the actuators 3, the intermediate circuit voltage Uzk rises above the upper limit value Ufr for releasing power supply peaks (regenerative power supply peaks). Before this happens, the regenerative power Pr is 1.1 times the rated power Pnenn of the
    Power supply network limited (with the corresponding distribution of the system power 1 to the recovery power Pr and the charging power P | _). In this
    Case is the rated power Pnenn for extracting energy from the
    Power supply network 4 equal to the nominal power Pnenn of the
    Power supply network 4 for the return of energy into the network. Of course, the embodiments may be readily adapted to accommodate any asymmetry in this regard.
    As soon as the intermediate circuit voltage Uzk rises above the upper limit value Ufr, according to the flow diagram from FIG. 3b, the maximum recovery power Pr, max is switched on. Again, the appropriate visualization of the
    System performance 2, in this case referred to the maximum recovery power Pr, max and the charging power Pl. It is then checked whether the intermediate circuit voltage Uzk has fallen below the upper threshold Usr again to block the recovery peaks. If this is not the case, the maximum feedback is allowed. If this is already the case, the cycle in the flowchart starts again, analogously to FIG. 2b.
    Also in this case, the time period TR, over which maximum recovery powers are permitted, can be recognized. Again, this guarantees the achievement of a stable state of the DC link 2 after increased voltage. Analogous statements regarding the maximum cycle power Pe.zykius.max, the maximum restricted power 1.1 Pnenn + Pi_, max and the limit of 1.1 Pnenn for the recovery power PR are analogous to those with respect to FIG. 2a. The fall of the feedback power PR into the negative area marks the extraction of energy from the power grid 4.
    It should be noted that the similar appearance of the total braking power braking cycle and the total motor power PMotorZykius of Figure 2a have only the same appearance in order to convey the principle of the invention easily. In reality, PBremsenzykius and PMotorZykius will not look the same, especially since PBremsenzykius = " PMotorZykius-
    Of course, an embodiment in which both the arrangements of Figures 2a and 2b and 3a and 3b are realized, not only conceivable, but preferred.
    权利要求:
    Claims (16)
    [1]
    Claims 1. A power supply device for a forming machine, comprising - an intermediate circuit (2) which is connectable to at least one drive (3) of the shaping machine, a power supply network (4) and an energy store (5), - a measuring device (6) for measuring an electrical voltage ( Uzk) or an electric current at the intermediate circuit (2) and - a control device (7), by means of which an energy transfer between the power supply network (4) and the intermediate circuit (2) in dependence of the measured voltage (Uzk) or the measured current is regulated, characterized in that the control device (7) is designed to increase a power supply (PN) provided by the power supply network (4) at the intermediate circuit (2) if the measured voltage (Uzk) or the measured current leaves a first range and to reduce the network power in absolute terms if the measured voltage (Uzk) or the measured current in a second area, the second area being smaller than the first area and being completely contained in the first area.
    [2]
    A power supply device according to claim 1, characterized in that the control means (7) is arranged to increase a grid power (Pn) provided by the power grid (4) at the intermediate circuit (2) if the measured voltage (Uzk) or the measured current is lower Limit (Ufn) falls below, and the grid power (Pn) reduce if the measured voltage (Uzk) or the measured current exceeds a lower threshold (Usn), wherein the lower threshold value (Usn) is greater than the lower limit (Ufn).
    [3]
    A power supply device according to claim 1 or 2, characterized in that the control device (7) is adapted to increase a regenerative power (Pr) provided by the intermediate circuit (2) at the power supply network (4) if the measured voltage (UZk) or the measured current is an upper one Limit (Ufr) exceeds, and the feedback power (PR) to reduce, if the measured voltage (Uzk) or the measured current below an upper threshold (USr), wherein the upper limit (Ufr) is greater than the upper threshold (Usr) ,
    [4]
    4. Energy supply device according to one of claims 1 to 3, characterized in that the intermediate circuit (2) has a - preferably parallel connected - intermediate circuit capacitor (8).
    [5]
    5. Power supply device according to one of claims 1 to 4, characterized in that the measuring device (6) is designed as a voltage measuring device and the measured voltage (Uzk) or the measured current is at the intermediate circuit (2) applied intermediate circuit voltage (Uzk), wherein the intermediate circuit voltage (Uzk) preferably is an electrical voltage applied to the intermediate circuit capacitor (8).
    [6]
    6. Energy supply device according to one of claims 1 to 5, characterized in that the control device (7) is adapted to increase the network power (PN) amount to a maximum network power (Pn.max, Pr, max), if the measured voltage (Uzk) or the measured current leaves the first region.
    [7]
    Power supply device according to one of Claims 1 to 6, characterized in that the control device (7) is designed to limit the power (PN) in terms of amount to a fixed multiple, preferably 1.1 times, a rated power (Pnenn) of the power supply network, when the measured voltage (Uzk) or the measured current enters the second range.
    [8]
    8. Power supply device according to one of claims 1 to 7, characterized in that with the intermediate circuit (2) connected to the power supply module (11) is provided, by means of which electrical energy between the power supply network (4) and the intermediate circuit (2) is transferable.
    [9]
    9. Power supply device according to claim 8, characterized in that the power supply module (11) has a rectifier (12) connected to the intermediate circuit (2) for rectifying an AC voltage supplied by the power supply network (4).
    [10]
    Power supply device according to claim 8 or 9, characterized in that the power supply module (11) has an inverter (13) connected to the intermediate circuit (2) for supplying an electrical power recovery voltage to the power supply network (4).
    [11]
    A molding machine having a power supply device according to any one of claims 1 to 10.
    [12]
    Forming machine according to claim 11, characterized in that the intermediate circuit (2) is connected to the at least one drive (3), in particular a closing drive and an injection drive, the forming machine or an energy store (5).
    [13]
    A forming machine according to claim 12, characterized in that said energy storage (5) comprises at least one storage capacitor (9) for storing electrical energy.
    [14]
    A forming machine according to claim 13, comprising a power supply device (1) according to claim 4, characterized in that a capacity of the at least one storage capacitor (9) is preferably larger by a factor of 10 to 30 than a capacity of the intermediate circuit capacitor (8).
    [15]
    15. Forming machine according to claim 13 or 14, characterized in that the intermediate circuit (2), preferably via a network connection module (11), with the power supply network (4) is connected.
    [16]
    Method for supplying energy to a forming machine, wherein - at least one drive (3) of the forming machine is supplied with electrical energy via an intermediate circuit (2) and - a voltage (Uzk) or a current is measured at the intermediate circuit (2), characterized in that - a first range and a second range for the measured voltage (Uzk) or the measured current is determined, wherein the second range is smaller than the first range and is completely contained in the first range, and - one from the power supply network (4) at a DC link power supply (Pn) is increased in magnitude if the measured voltage (Uzk) or the measured current leaves the first range, and the net power (Pn) is reduced in magnitude if the measured voltage (Uzk) or the measured current enters the second range.
    类似技术:
    公开号 | 公开日 | 专利标题
    DE102015108889B4|2021-10-07|Motor control device with protection unit of a charging resistor
    DE102014209332A1|2015-11-19|Wind turbine with improved overvoltage protection
    EP2610049B2|2022-02-09|Method for controlling a hydraulic press
    AT515985B1|2019-06-15|Power supply device
    DE102012101928A1|2012-09-13|Power grid decentralized stabilizing method, involves minimizing feed-in power of power grid decentralized stabilizing system in relation to actual maximum generator power according with requirements for feed-in power
    EP2701299B1|2018-09-26|Method and device for the intermediate storage of electrical energy
    WO2013045072A2|2013-04-04|Pv system having a safeguard against feeding into a public power distribution network
    EP2541746B1|2021-01-20|Method for discharging a direct link capacitor at a converter and respectiveelectrical circuit
    EP2200169B1|2014-04-02|Method for starting a doubly-fed induction machine
    DE102010025647A1|2011-12-15|Device for controlling electrical power supplied to e.g. press device, has interface to allow current flow between power supply network and intermediate circuit, when voltage value in intermediate circuit lies within target voltage range
    EP2144361B1|2017-03-29|Method and device for regulating the regenerative power of a base frequency clocked inverter
    WO2012019834A2|2012-02-16|Converter system and method for operating such a converter system
    EP2763276A1|2014-08-06|Converter and method for operating same
    DE202015101806U1|2015-04-27|Renewable Energy Plant and Renewable Energy Park
    DE102014217657A1|2015-04-16|Inverter for solar power generation
    DE102015200249A1|2016-07-14|Supply circuit for supplying a welding device
    EP2580834B1|2019-12-18|Predictable feeding of reactive powers
    DE102016206053A1|2016-11-24|Protection circuit for braking resistor
    DE102011003459A1|2012-08-02|Electrical circuit for a wind farm
    DE10138399A1|2003-02-27|Operating wind energy plant involves regulating power delivered from generator to electrical load, especially of electrical network, depending on current delivered to the load
    EP2677622B1|2019-11-20|Method and a device for feeding electrical power to an electrical energy supply network
    DE102019101048A1|2020-07-16|Wind turbine for feeding electrical power into an electrical supply network
    DE102008064079A1|2010-06-24|Electrical circuit producing method for producing electrical energy in e.g. gas turbine-power plant, involves interconnecting two poles of intermediate circuit by adjustable resistor when intermediate circuit voltage increases
    DE102012017851A1|2013-12-19|Electric circuit arrangement for operating electrical load e.g. alternating current powered electric motor, has charging device having energy storage unit that supplies power to electrical load, when failure of power supply is detected
    DE102011014468A1|2012-09-20|Inverter used in wind-power plant, supplies predetermined amount of unbalanced reactive power of generator into three-phase power supply networks, based on request of control signal
    同族专利:
    公开号 | 公开日
    CN105356489B|2018-11-16|
    DE102015008436A1|2016-01-07|
    CN105356489A|2016-02-24|
    US20160072295A1|2016-03-10|
    DE102015008436B4|2022-02-24|
    AT515985B1|2019-06-15|
    US10014694B2|2018-07-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE4131823C1|1991-09-20|1993-02-04|Licentia Patent-Verwaltungs-Gmbh, 6000 Frankfurt, De|Bidirectional power supply circuitry between AC and DC networks - holds intermediate DC at high level using two rectifiers with common connections on DC and AC sides|
    US20080259666A1|2004-09-30|2008-10-23|Honda Motor Co., Ltd.|Power Unit|
    DE102007024567A1|2007-05-25|2008-11-27|Daimler Ag|High-voltage on-board network architecture for a fuel cell vehicle and integrated power electronics for a high-voltage vehicle electrical system architecture|
    US20110273148A1|2010-05-06|2011-11-10|Honda Motor Co., Ltd.|Output control device for hybrid engine-driven power generator|
    DE10159645B4|2001-12-05|2010-04-08|Siemens Ag|Method and device for maintaining a supply voltage of a power supply electronics of a matrix converter in case of power failure|
    US6975525B2|2002-11-14|2005-12-13|Fyre Storm, Inc.|Method of controlling the operation of a power converter having first and second series connected transistors|
    DE102010023536A1|2010-06-11|2011-12-15|Robert Bosch Gmbh|Smart net capacity control device for automatic control engineering device e.g. press device, has flywheel energy storage provided with electromotor, and processor reading received information with rotation speed of flywheel energy storage|
    DE102010025647A1|2010-06-11|2011-12-15|Robert Bosch Gmbh|Device for controlling electrical power supplied to e.g. press device, has interface to allow current flow between power supply network and intermediate circuit, when voltage value in intermediate circuit lies within target voltage range|
    CN103001238B|2011-09-19|2014-08-06|上海三菱电梯有限公司|Elevator energy saving system|
    EP2684732A1|2012-07-09|2014-01-15|ABB Oy|Electrical system having a DC link|CN105552944B|2016-02-26|2017-12-01|东北大学|A kind of network system and energy adjustment method comprising energy storage and energy router|
    DE102016207579A1|2016-05-03|2017-11-09|Robert Bosch Gmbh|MULTIPURPOSE AXIS EQUIPMENT AND METHOD FOR OPERATING A MULTIPURPOSE AXLE EQUIPMENT|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA539/2014A|AT515985B1|2014-07-07|2014-07-07|Power supply device|ATA539/2014A| AT515985B1|2014-07-07|2014-07-07|Power supply device|
    DE102015008436.4A| DE102015008436B4|2014-07-07|2015-06-30|shaping machine|
    US14/791,823| US10014694B2|2014-07-07|2015-07-06|Power supply apparatus|
    CN201510650004.9A| CN105356489B|2014-07-07|2015-07-07|Power supply, molding machine and the method for supplying energy to molding machine|
    [返回顶部]