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In this paper, an approach towards energy management 4.0 will be presented. Energy management 4.0 is understood as an encompassing energy data based concept for manufacturing companies acting in an flexible energy grid of the future with the final goal of autonomous self-optimization Controlling, supervising and scheduling production and logistic steps based on a reliable communication infrastructure and real time data in accordance to achieve a maximum of profitability with regard to human factor is executed.
Guided by a four maturity levels of the "acatech Industrie 4.0 Maturity Index" developed by the German National Academy of Science and Engineering (acatech) different use cases are presented according to the steps of visibility, transparency, prognostic capacity and self-optimization. The basic idea of energy management 4.0 is described and an outlook of further steps that are needed to be evaluated for an implementation are presented.
Due to the drastically increasing amount of data, decision making in companies heavily relies on having the right data available. Also because of an increasing complexity of structures and processes, quick and precise flows of information become more important.
This paper introduces a new approach for modelling information flows, creating a basis for an efficient information management. It can be used to structure the information requirements and identify gaps within the information processing.
To display its benefits, the proposed Information Logistics Notation (ILN) is applied to the information logistics of todays and future energy market and grid stability management, both processes of increasing complexity.
In order to introduce load management in the manufacturing industry, some obstacles need to be pointed out. This paper presents a feasible approach on how to implement load management measures in companies.
To this end, load management and energy management are explained and distinguished in a first step. Subsequently, the implementation method is introduced. Therefore, by means of this paper, companies will be enabled to use load management measures and significantly reduce their energy costs. In the second part of the paper, the introduced approach will be applied.
Hence, a use case of a manufacturing company is described. Alongside energy analyses with consumption data, specific measures are presented.
In order to introduce load management in the manufacturing industry, some obstacles need to be pointed out. This paper presents a feasible approach on how to implement load management measures in companies. To do so, load management and energy management are explained and distinguished in a first step. Subsequently, the implementation method is introduced. Therefore, by using this paper, companies will be enabled to use load management measure and reduce their energy costs significantly.
Increasing the energy efficiency and meanwhile avoiding unplanned maintenance breaks are keys for manufacturing companies to stay competitive in the future. This paper presents an energy saving and maintenance cost reducing approach for manufacturing environments. The approach describes first occurring types of energy wastage within manufacturing and characterizes them in more detail. Including additional external information, the significance of an identified on-going wastage can be determined. Based on the type of wastage and the significance; concrete recommendations for measures to prevent the wastage are delivered. The identified wastage facilitates detecting inefficient operating mode as well as wearing and malfunctioning at machines. By using complex event processing technologies realtime information can forwarded directly to the responsible persons to enable quick reactions to prevent energy wastage and unplanned downtimes. The paper presents an approach to identify detection and propose concepts for manufacturing enterprises. The information processing procedure is used for the implementation of two Use Cases.
Die digitale Transformation in Unternehmen bewirkt einen stetigen Anstieg der Datenmengen auf allen Unternehmensebenen. Die Nutzung dieser Daten und deren Veredlung zu Informationen gestalten sich aufgrund der historisch gewachsenen IT-Komplexität jedoch zunehmend als strukturelle und organisatorische Herausforderung. Das Potenzial der digitalen Transformation, schnellere und bessere Entscheidungen auf Basis von Analysen der vorliegenden Datenbasis zu treffen, bleibt damit oftmals hinter den Erwartungen zurück. Unternehmen sind daher gefordert, Strukturen und Fähigkeiten zur Beherrschung der Ressource Information zu gestalten. Die Informationslogistik stellt einen essenziellen Baustein dar, um interne und externe Informationsflüsse effektiv und effizient nutzbar zu machen.
Heutzutage werden Konstruktionsprojekte von großen, interdisziplinären und meist räumlich getrennt arbeitenden Teams geplant und durchgeführt. Dabei haben Projektmitarbeiter unterschiedliche Datensätze, die oft über einen komplexen und fehleranfälligen E-Mail-Verkehr ausgetauscht werden. Dies führt zu einer schwerfälligen und meist chaotischen Datenspeicherung. Im Folgenden wird eine dreistufige hybride Cloudspeicherungslösung beschrieben, die den Datenaustausch durch vorausplanende Datensynchronisation verbessern soll. Anschließend wird, mit Blick auf die Verwendbarkeit des Systems, ein Kommunikationsmodell zur effizienten Zusammenarbeit vorgestellt. Ziel des Projekts ist es, eine cloudbasierte Collaboration-Software für die Baubranche zu entwickeln, die die Qualität und Geschwindigkeit von Konstruktionsprozessen nachhaltig erhöht und Fehler durch alte oder falsche Daten reduziert. Das Projekt wird mit Mitteln der Europäischen Union (EU) gefördert.
Thanks to the challenges of the imminent energy turnaround, the power market faces a revolution regarding the energy distribution. In future, energy will not only be distributed from a limited number of large, centralized power plants but also from small, decentralized power generators, e.g. households. This also affects manufacturing companies, which are confronted with developing an energy management strategy. As those companies usually have not set high priorities on their energy management, there is a lack of a structured procedure to build an energy management strategy. Consequently, this creates the need for supporting methods to develop and implement an energy management strategy. This paper tackles the first step in the development of an energy management strategy. For this purpose, a target map is developed and possible use cases are systematized. The next steps of the implementation are presented using the example of load management.
Im Strommarkt 2.0 wird ein Paradigmenwechsel von einer verbrauchsorientierten Erzeugung zu einem erzeugungsorientierten Verbrauch durchlaufen. Dies erfordert in Zukunft ein gesteigertes Angebot von Flexibilität. Die Idee und die für das Energiesystem dienlichen Potentiale eines Flexibilitätsmarktes für die Industrie sind bekannt, dennoch werden diese Möglichkeiten zurzeit nur eingeschränkt genutzt. Es stellt sich somit die Frage, durch welche Anreize und Dienstleistungen es gelingen kann, Unternehmen zur Bereitstellung von Flexibilität zu motivieren. Hierfür werden im vorliegenden Paper die bestehenden Energiedienstleistungen und neue Flexibilitätsdienstleistungen strukturiert beschrieben und Potenziale herausgestellt.