Abstract: Pallet (1) comprised of at least one loading plane (2), on which goods or the like are placed during use of the pallet, and at least one pallet foot (3) or several pallet feet (3). The loading plane (2) is comprised of at least one first material layer (10) of corrugated fiberboard and at least one second material layer (11) of corrugated fiberboard and at least one third material layer (14) of corrugated fiberboard which are joined together by gluing. The adjacent material layers' corrugated mediums are twisted in relation to one another. The loading plane (2) is further comprised of at least one surrounding covering that encloses or essentially encloses the material layers and that the enclosing covering is comprised of at least one first shroud (8) and at least one second shroud (9) of water repellent or water resistant material. In alternative embodiments, the pallet is comprised of at least one pallet collar (4).

Abstract: A controller includes a sampling module that samples a signal indicative of the output voltage, a filter module that filters out a ripple component of a sampled signal to generate a filtered signal, and a proportional-integral-derivative (PID) controller that generates a duty cycle control signal. The PID controller includes a first component that scales sample values of the filtered signal to generate a first component signal, a down-sampling module that generates a down-sampled signal, and a storage module that stores a value of the down-sampled signal. The PID controller also includes a second component that generates a second component signal as a product of a factor and a difference signal between each sample value in the filtered signal and stored value, a third component that scales and accumulates the down-sampled signal to generate a third component signal, and a summing module that sums the first, second and third component signals.

Abstract: A controller, and related method, configured to generate a duty cycle control signal for controlling an output voltage of a switched mode power supply as a function of a reference signal. In one embodiment, the controller is configured to sample a signal indicative of the output voltage to generate a first sampled signal, filter out a ripple component of the first sampled signal to generate a filtered signal, and generate a feedback control signal based on the filtered signal. The controller is also configured to sample a signal indicative of an input voltage of the switched mode power supply to generate a second sampled signal, generate a feed-forward control signal based on the second sampled signal and a feed-forward reference voltage, and generate the duty cycle control signal based on the feedback control signal and the feed-forward control signal.

Abstract: A controller includes a sampling module that samples a signal indicative of the output voltage, a filter module that filters out a ripple component of a sampled signal to generate a filtered signal, and a proportional-integral-derivative (PAID) controller that generates a duty cycle control signal. The PAID controller includes a first component that scales sample values of the filtered signal to generate a first component signal, a down-sampling module that generates a down-sampled signal, and a storage module that stores a value of the down-sampled signal. The PAID controller also includes a second component that generates a second component signal as a product of a factor and a difference signal between each sample value in the filtered signal and stored value, a third component that scales and accumulates the down-sampled signal to generate a third component signal, and a summing module that sums the first, second and third component signals.

Abstract: An apparatus for a power system with a power input at an upstream end and power outputs connected to loads in a downstream end, the power system comprising a plurality of devices interconnected in a tree topology. The apparatus communicatively coupled to each of the devices and configured to identify each of the devices, cause a change of an operation state or parameter of each of the devices at a time. The apparatus further configured to determine, for each of the devices having an operation state or parameter thereof changed, which of the other devices having a related change of an operation state or parameter thereof, and identify how the devices are connected in the tree topology based on said determined other devices having a related change of an operation state or parameter thereof, for each of said devices having an operation state or parameter thereof changed.

Abstract: A controller, and related method, configured to generate a duty cycle control signal for controlling an output voltage of a switched mode power supply as a function of a reference signal. In one embodiment, the controller is configured to sample a signal indicative of the output voltage to generate a first sampled signal, filter out a ripple component of the first sampled signal to generate a filtered signal, and generate a feedback control signal based on the filtered signal. The controller is also configured to sample a signal indicative of an input voltage of the switched mode power supply to generate a second sampled signal, generate a feed-forward control signal based on the second sampled signal and a feed-forward reference voltage, and generate the duty cycle control signal based on the feedback control signal and the feed-forward control signal.

Abstract: An apparatus for power system with a power input at an upstream end and power outputs connected to loads in a downstream end, the power system comprising a plurality of devices interconnected in a tree topology, The apparatus communicatively coupled to each of the devices and configured to identify each of the devices, cause a change of an operation state or parameter of each of the devices at a time. The apparatus further configured to determine, for each of the devices having an operation state or parameter thereof changed, which of the other devices having a related change of an operation state or parameter thereof, and identify how the devices are connected in the tree topology based on said determined other devices having a related change of an operation state or parameter thereof, for each of said devices having an operation state or parameter thereof changed.

Abstract: A controller (500) for determining a distribution of switching phases among switching elements of a power supply system The power supply system has a plurality of voltage converters, each comprising a switching element and being arranged to convert an input voltage supplied to the voltage converters to a respective output voltage by switching the switching element at a predetermined frequency. The controller (500) comprises a receiver (510) for receiving one or more signals indicative of a respective contribution from each of the voltage converters to a ripple current component of an input current of the voltage converters, and a rank determining module (520) configured to rank the voltage converters in order of decreasing contribution to the ripple current.

Abstract: A controller for determining switching phases among switching elements of a power supply system having voltage converters, each comprising a switching element. The controller receives signals indicative of a contribution from each converter to a ripple voltage component of an input current of the converters, and ranks the converters. The controller calculates a switching phase offset that is to be applied for the switching element by: (i) calculating phase offsets of two highest ranked converters that would minimize an input voltage ripple caused by said two highest ranked converters, (ii) calculating a phase offset of a next-highest ranked converter that would minimize an input voltage ripple caused by said next-highest ranked converter and converters ranked higher than said next-highest converter; and (iii) repeating step (ii) for each converter in the ranking. The controller generates output signals defining the calculated switching phase offsets to be applied to the switching elements.

Abstract: A controller (500) for determining a distribution of switching phases among switching elements of a power supply system The power supply system has a plurality of voltage converters, each comprising a switching element and being arranged to convert an input voltage supplied to the voltage converters to a respective output voltage by switching the switching element at a predetermined frequency. The controller (500) comprises a receiver (510) for receiving one or more signals indicative of a respective contribution from each of the voltage converters to a ripple current component of an input current of the voltage converters, and a rank determining module (520) configured to rank the voltage converters in order of decreasing contribution to the ripple current.

Abstract: A voltage converter (200) is disclosed, which comprises a controller (210) operable in: a first mode to control the voltage converter so as to convert an input voltage (Vin) at an input (230) of the voltage converter to an output voltage (Vout) at an output (240) of the voltage converter; and a second mode, in which the controller (210) is configurable by configuration control signals (270) so as to change the control applied by the controller to the voltage converter. The voltage converter (200) also includes a power module (280) arranged to derive and supply an operation voltage (Voperation) to the controller (210), the power module (280) being arranged to derive the operation voltage from the input voltage (Vin) during operation of the controller (210) in the first mode, and a voltage source (340) other than the input voltage (Vin) during operation of the controller (210) in the second mode.

Abstract: A voltage controller (700) operable to generate control signals for controlling an intermediate bus voltage (VIB) in an intermediate bus architecture power system (100), the intermediate bus voltage comprising a voltage output from a first stage DC/DC power converter (200) to at least one second stage DC/DC power converter (500-1 to 500-K). The voltage controller (700) comprises a receiver operable to receive at least one of voltage and current values input to the first stage DC/DC power converter (200). The voltage controller (700) further comprises a efficiency measuring unit operable to determine a measure of the efficiency of the intermediate bus architecture power system in accordance with the received values, and a control signal generator operable to generate control signals in dependence upon the determined efficiency measure to cause the first stage DC/DC converter (200) to set the intermediate bus voltage (VIB).

Abstract: A controller for determining switching phases among switching elements of a power supply system having voltage converters, each comprising a switching element. The controller receives signals indicative of a contribution from each converter to a ripple voltage component of an input current of the converters, and ranks the converters. The controller calculates a switching phase offset that is to be applied for the switching element by: (i) calculating phase offsets of two highest ranked converters that would minimise an input voltage ripple caused by said two highest ranked converters, (ii) calculating a phase offset of a next-highest ranked converter that would minimise an input voltage ripple caused by said next-highest ranked converter and converters ranked higher than said next-highest converter; and (iii) repeating step (ii) for each converter in the ranking. The controller generates output signals defining the calculated switching phase offsets to be applied to the switching elements.

Abstract: The invention relates to a range determining device for a voltage controller of an intermediate bus voltage (VIB) in an intermediate bus architecture power system, an intermediate bus architecture power system as well as to a method, computer program and computer program product of providing a range within which a controlled intermediate bus voltage in an intermediate bus architecture power system is allowed to vary. The range determining device obtains a range (R3) for the controlled intermediate bus voltage, which range has been determined based on statistical data corresponding to a current time interval of the control, and provides the range to the voltage controller for the voltage controller to control the intermediate bus voltage (VIB) within the determined range in a current time interval.

Abstract: A power supply system controller for configuring voltage converters in a power supply system comprises a first voltage converter arranged to convert an input voltage at an input of the first voltage converter to an output voltage at an output of the first voltage converter, wherein the output of the first voltage converter is connected to an input of a second voltage converter. Each of the first and second voltage converters comprises a controller configurable by received first control signals to control the voltage conversion to be performed by the voltage converter, and a power module arranged to derive, from the input of the voltage converter, an operation voltage (Voperation) to power the controller such that the controller can be configured by the received first control signals.

Abstract: A method for preparing a current measuring arrangement of a switched mode power supply comprising a switched mode converter, and a controller for controlling the switched mode converter to convert an input voltage to an output voltage by means of controlling the duty cycle, is provided. A model, in which the output current of the converter is determined from variables and one or more model parameters, wherein the variables comprise the input voltage, the output voltage, and the duty cycle, is formed. The variables are varied while the output current is measured. The one or more model parameters is/are estimated from the varied variables and the measured output current by means of regression analysis and the model and the one or more estimated model parameters to be used by the current measuring arrangement during use of the switched mode power supply are stored.

Abstract: In an intermediate bus architecture power system, a voltage controller that generates control signals for controlling an intermediate bus voltage (VIB) output from a first stage DC-to-DC power converter to at least one second stage DC-to-DC power converter via the intermediate voltage bus. A receiver receives values of the current input to the first stage converter, or the current and voltage output by the first stage converter. The controller determines a first value of an efficiency measure using the received values corresponding to a first VIB, and determines a second value of the efficiency measure for a second VIB higher than the first VIB.

Abstract: A voltage converter (200) is disclosed, which comprises a controller (210) operable in: a first mode to control the voltage converter so as to convert an input voltage (Vin) at an input (230) of the voltage converter to an output voltage (Vout) at an output (240) of the voltage converter; and a second mode, in which the controller (210) is configurable by configuration control signals (270) so as to change the control applied by the controller to the voltage converter. The voltage converter (200) also includes a power module (280) arranged to derive and supply an operation voltage (Voperation) to the controller (210), the power module (280) being arranged to derive the operation voltage from the input voltage (Vin) during operation of the controller (210) in the first mode, and a voltage source (340) other than the input voltage (Vin) during operation of the controller (210) in the second mode.

Abstract: A controller (500) for determining a distribution of switching phases among switching elements of a power supply system The power supply system has a plurality of voltage converters, each comprising a switching element and being arranged to convert an input voltage supplied to the voltage converters to a respective output voltage by switching the switching element at a predetermined frequency. The controller (500) comprises a receiver (510) for receiving one or more signals indicative of a respective contribution from each of the voltage converters to a ripple current component of an input current of the voltage converters, and a rank determining module (520) configured to rank the voltage converters in order of decreasing contribution to the ripple current.

Abstract: A method of determining a measure of a total capacitance of one or more capacitive elements connected to an output of a switched mode power supply is described. The method includes generating a voltage control signal to cause an output voltage controller to sweep a voltage at the output of the switched mode power supply from an initial voltage value to a final voltage value. Sample values of a current at the output measured by a current sampler during the sweep of the output voltage are received, and an integrated current value representing a measure of the total capacitance using the received sample values is calculated.