The upgrade of NIM-2 joule balance since 2017

The Planck-Balance is a table-top version of a Kibble balance, developed in a collaboration between the PTB and TU Ilmenau. In contrast to most Kibble balances, where the motion range is of up to several centimetres in the velocity mode, in the Planck-Balance it is below 100 μm. For a reliable determination of the force factor, the voice coil is set into harmonic oscillation, resulting in an induced AC voltage. The amplitude of the first harmonic is then taken to determine the force factor. However, due to the non-linear magnetic field across the motion range, the first harmonic is subject to a bias, and higher harmonics are excited. Those higher harmonics contain the information about the relative magntitude of the bias in the first harmonic, and can be used for a correction. In this paper we present an analytical model and show its application with real measurements. The estimated relative bias amounts to −6.3·10−6, with a residual relative uncertainty of 6.3 · 10−7, for an oscillation amplitude of 20 μm. This method is especially of importance for Kibble balances with short motion range and working with harmonic oscillation. After such a correction is applied, a table-top version of a Kibble balance can be used as a conventional balance calibrated by means of E2 mass standards in the whole E2 class mass range.

Section: Introductionmentioning

confidence: 99%

A method for evaluating the force factor in oscillating Kibble balances with application to the Planck-Balance

Rothleitner,

Poroskun,

Svitlov

et al. 2023

“…Moreover, the primary realization of the unit is separated conceptually from the definition so that the mise en pratique may be improved as science and technology develop. Currently, two complementing primary realization methods have the capability for realizing the kilogram with the required uncertainty: the Kibble balance (KB) [2][3][4][5][6][7][8][9][10][11][12][13] and the x-ray crystal density [14][15][16]. Although the target uncertainty was achieved by the individual experiments, the submitted Planck constant data to CODATA in 2017 was not statistically consistent [17].…”

Section: Introductionmentioning

confidence: 99%

UME Kibble balance operating in air

Ahmedov¹,

Orhan²,

Korutlu³

2022

The UME KB-3 operating since 2020 allows the realization of kilogram under ambient air conditions owing to its distinguishing design and operation protocol. This is possible only because the coil pair is stationary but the surrounding magnet assembly is moving. The mechanically decoupled nature of the magnet assembly allows the implementation of a local vacuum for displacement measurements rather than a vacuum covering the entire apparatus. The balance operates in single mode with simultaneous operation of weighing and moving phases instead of successive phases. A novel dynamical measurement procedure is developed in order to conform with the single phase measurements. The paper describes the apparatus and presents the measurement results for stainless steel mass artefact with a nominal value of 1 kg. The mass of the artefact is measured with a total relative uncertainty of 54 ppb.

“…From May 20, 2019, the kilogram, the unit of mass, was redefined based on the Planck constant [1]. The joule balance, derived from the Kibble balance, is one of the methods used to measure the mass from the Planck constant at 10 −8 relative uncertainty level [2,3]. The basic principle of the Kibble balances and the joule balance is to use the electromagnetic force to balance the gravity of the measured mass [4][5][6][7].…”

Section: Introductionmentioning

confidence: 99%

“…In the second generation of the joule balance NIM-2, fine-tuning mechanics have been used to adjust the horizontal position and posture of the suspended coil, and this process could be performed in a vacuum [26]. Although this development can largely reduce the alignment uncertainty to less than 5 × 10 −8 [3,27], the adjustment was still complicated to achieve due to the strong coupling between the horizontal forces and torques. To solve this problem, this study proposes an automatic technique and system to minimize horizontal forces and torques.…”

Section: Introductionmentioning

confidence: 99%

Automatic alignment technique for the suspended coil in the joule balance

Bai¹,

Wang²,

Li³

et al. 2021

Self Cite

An automatic alignment technique was developed for the joule balance to reduce the uncertainty caused by alignment errors. Using the flexures and decoupling structure of the suspended coil, the proposed alignment system can automatically recognize the linear relationship between the initial position and posture of the suspended coil when the current is off, and its parasitic horizontal linear and angular displacements when the current is on. Subsequently, several actuators including mini-motors and an X-Y stage are controlled to adjust the position and posture of the coil, minimizing the parasitic forces and torques and reducing them by approximately 100 times in comparison with the alignment results of the joule balance obtained in 2019, whilst maintaining the adjustment time to several minutes only.