Bucket wheel excavators: Dynamic response as a criterion for validation of the total number of buckets

“…, 64), created for the BWE SchRs 1600 (Figure 2). The procedure for the formation and validation of the model, which has already been successfully used to analyze the impacts of the number of buckets [56], the counterweight mass [57], as well as incrustation and chute blockage [58] on the dynamic response of the structure, is described in detail in [59].…”

“…A study on the impact of the bucket-wheel frequency of revolution, i.e., the frequency of revolution of the bucket-wheel drive electromotor (FREM), on the dynamic response of the referent points of the structure, determined in accordance with the standard [52], was conducted using a spatial reduced dynamic model of the slewing superstructure with 64 degrees of freedom (generalized coordinates qs, s = 1, 2, …, 64), created for the BWE SchRs 1600 (Figure 2). The procedure for the formation and validation of the model, which has already been successfully used to analyze the impacts of the number of buckets [56], the counterweight mass [57], as well as incrustation and chute blockage [58] on the dynamic response of the structure, is described in detail in [59]. was formed by applying the Lagrange's second-order equations, A system of differential equations of motion (vibrations) of the model under the action of the excitation caused by the resistance to excavation,…”

“…As is already known, in BWEs, the fundamental frequency of excitation caused by the forces resisting excavation depends on two crucial parameters of the excavating device, i.e., it is proportional to the number of buckets and the bucket-wheel frequency of revolution. The impact of the number of buckets on the dynamic behavior of the BWE slewing superstructure, under the nominal frequency of the bucket-wheel revolution, is analyzed in detail in [56]. Below is presented a study on the impact of the bucket-wheel frequency of revolution of the dynamic behavior of the BWE slewing superstructure as a basis for the implementation of the proposed idea, which, simultaneously and fully, both methodologically and operatively, solves the problem of the selection of the key parameters of the BWE excavating device and their impact on the dynamic response of its slewing superstructure.…”

Analysis of the Dynamic Response as a Basis for the Efficient Protection of Large Structure Health Using Controllable Frequency-Controlled Drives

“…, 64), created for the BWE SchRs 1600 (Figure 2). The procedure for the formation and validation of the model, which has already been successfully used to analyze the impacts of the number of buckets [56], the counterweight mass [57], as well as incrustation and chute blockage [58] on the dynamic response of the structure, is described in detail in [59].…”

“…A study on the impact of the bucket-wheel frequency of revolution, i.e., the frequency of revolution of the bucket-wheel drive electromotor (FREM), on the dynamic response of the referent points of the structure, determined in accordance with the standard [52], was conducted using a spatial reduced dynamic model of the slewing superstructure with 64 degrees of freedom (generalized coordinates qs, s = 1, 2, …, 64), created for the BWE SchRs 1600 (Figure 2). The procedure for the formation and validation of the model, which has already been successfully used to analyze the impacts of the number of buckets [56], the counterweight mass [57], as well as incrustation and chute blockage [58] on the dynamic response of the structure, is described in detail in [59]. was formed by applying the Lagrange's second-order equations, A system of differential equations of motion (vibrations) of the model under the action of the excitation caused by the resistance to excavation,…”

“…As is already known, in BWEs, the fundamental frequency of excitation caused by the forces resisting excavation depends on two crucial parameters of the excavating device, i.e., it is proportional to the number of buckets and the bucket-wheel frequency of revolution. The impact of the number of buckets on the dynamic behavior of the BWE slewing superstructure, under the nominal frequency of the bucket-wheel revolution, is analyzed in detail in [56]. Below is presented a study on the impact of the bucket-wheel frequency of revolution of the dynamic behavior of the BWE slewing superstructure as a basis for the implementation of the proposed idea, which, simultaneously and fully, both methodologically and operatively, solves the problem of the selection of the key parameters of the BWE excavating device and their impact on the dynamic response of its slewing superstructure.…”

Analysis of the Dynamic Response as a Basis for the Efficient Protection of Large Structure Health Using Controllable Frequency-Controlled Drives

“…These are mainly the distances of the individual measuring instruments (GNSS, inclinometers, inclement speed sensors) in relation to each other and to some mechanical "nodes" of the excavator structure [9]. Subsequently, an algorithm [8] was developed that incorporated the results of the measurements of the individual measuring and gauging instruments and allowed calculations of the spatial position of the wheel centre in any general position of the excavator [10]. Somewhat more complex is the modelling of the shape of the material to be placed on the spoil heap by tracked stackers using the throw parabola [4].…”

System monitorowania położenia koparek i wielonaczyniowych węgla brunatnego i bezpieczeństwa ich pracy

“…Such activities may lead to modernization; an example is the bucket wheel [12]. The methods of extending the service of technical objects include efficiency improvements [24], reduction in the dynamic loads' impact [25,26], and work safety improvements [27][28][29].…”

The Assessment of the Technical Condition of Complex Fatigued Load-Carrying Structures