Wyniki wyszukiwania - BazTech

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The impact of the elevator guides contamination on the braking process delay for selected progressive gears

Longwic R., Szydło K.

Advances in Science and Technology. Research Journal

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2017

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Vol. 11, no 2

1--7

EN

The authors’ tests results on the impact of the guiding system (the guides) contamination in the friction lift on the delay of progressive gears braking process are presented in this article. The tests were conducted using a free fall method and a test bench built for that purpose. In order to render all working conditions the guiding system of tested gears was lubricated with the most commonly used lubricating agents. Solid grease (SM), mineral oil (OL), the mixture of solid grease and quartz sand (S50) as well as the mixture of mineral oil and quartz sand (O50) were used.

2

Savitzky-Golay method for the evaluation of deceleration of the friction lift

Lonkwic P., Szydło K., Molski S.

Advances in Science and Technology. Research Journal

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2017

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Vol. 11, no 1

138--146

EN

Due to self-acting variability of operating conditions during the work of lifting devices, it is fundamental for the gears to stop the cabin at any clearance height. The operating conditions are changed by dust contamination influencing a proper braking process of the gear. This article presents the independent tests results. The impact of progressive gear geometry on the braking distance both in variable operating conditions and variable loading is analyzed. The tests were conducted for the gear applied in short distance transportation devices. Changing operating conditions were obtained by using various lubricating agents. The following five types of the gears were used for the tests: ASG100, PP16, PR2000, KB160. CHP 2000 gear was tested as a new solution. The tests were conducted using a free fall method. The test results obtained from an experiment were approximated by using Savitzky-Golay method.

3

Theoretical and experimental analysis of loading impact from the progressive gear on the lift braking distance with the use of the free fall method

Lonkwic P., Różyło P.

Advances in Science and Technology. Research Journal

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2016

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Vol. 10, nr 30

103--109

EN

The gear which is the central safety element of the friction drive lift during braking is exposed to overloading connected with changeable weight which loads the lift braking system. In the article the results of numerical analysis for braking process of CHP 2000 type progressive gear distinguished by an innovative design have been presented. The numerical analysis was conducted with the use of a simulation of the gear roller displacement depending on changeable loading with the support of Abaqus/CAE software. Displacement of the gear roller from the neutral position in which the gear starts loosing energy of speeding up weight to zero was simulated. The results obtained from computer simulations were verified on the basis of a physical experiment at the bench station created to verify braking parameters of the gears with the use of free fall method.

4

Numerical and experimental analysis of the progressive gear body with the use of finite-element method

Lonkwic P., Różyło P., Dębski H.

Eksploatacja i Niezawodność

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2015

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Vol. 17, no. 4

544--550

EN

The article presents the results of experimental and numerical simulations of the braking process of new type CHP 2000 progressive gear roller. The gear which is a main element of the friction drive lift safety during braking is exposed to overloading connected with changeable weight loading the gear. Reliable operation of the braking system of the lift, especially in emergency situations, is the basis for the safe operation of these devices. Presented in this paper progressive gear design solution was subjected to tests on test stand and simulations numerical aimed at confirming the required strength and proper functionality of structures subjected to operational loads. Numerical analysis simulation was gear roller displacement during braking from the neutral position to the maximum displacement and the impact load on the alternating stress levels in the gripper elements. The results of numerical calculations verified by experimental studies, analyzing braking distance. The instrument used was a commercial numerical package for calculations using the finite element method – a program Abaqus®.

PL

W artykule zaprezentowano wyniki badań eksperymentalnych oraz symulacji numerycznych procesu hamowania rolki chwytacza progresywnego nowego typu CHP 2000. Chwytacz będący głównym elementem bezpieczeństwa dźwigu ciernego podczas hamowania narażony jest na przeciążenia związane ze zmienną masą obciążającą układ hamowania. Niezawodna praca układu hamowania dźwigu, zwłaszcza w sytuacjach awaryjnych, stanowi podstawę bezpiecznej eksploatacji tych urządzeń. Zaprezentowane w artykule rozwiązanie konstrukcyjne chwytacza progresywnego poddane zostało próbom stanowiskowym oraz symulacjom numerycznym, mającym na celu potwierdzenie wymaganej wytrzymałości oraz właściwej funkcjonalności konstrukcji poddanej obciążeniom eksploatacyjnym. Analizie numerycznej poddano symulację przemieszczenia rolki chwytacza w trakcie hamowaniaz pozycji neutralnej do pozycji maksymalnego przemieszczenia oraz wpływ zmiennego obciążenia na poziom naprężeń w elementach chwytacza. Wyniki obliczeń numerycznych weryfikowano badaniami eksperymentalnymi, poddając analizie długość drogi hamowania. Zastosowanym narzędziem numerycznym był komercyjny pakiet do obliczeń z wykorzystaniem metody elementów skończonych – program Abaqus®.