Volume- 8
Issue- 6
Year- 2021
DOI: 10.55524/ijirem.2021.8.6.65 | DOI URL: https://doi.org/10.55524/ijirem.2021.8.6.65
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0) (http://creativecommons.org/licenses/by/4.0)
Article Tools: Print the Abstract | Indexing metadata | How to cite item | Email this article | Post a Comment
Dr. Anubhav Soni , Mr. Pooran Singh
A transcutaneous strength transmission system was produced out of a few loops, which designed a transformer over the skin, a driving circuit, and an amending circuit. By using coreless loops and a high driving recurrence (100–160 kHz), beyond what 25 W of electric power might be transferred with 78.5 percent of maximum proficiency (dc to dc) (dc to dc). In creature testing, the critical loop temperature during activity was under 39°C on thermo-grams. Following 10 months of implantation of an auxiliary loop coated with epoxy pitch, it was wrapped by a thin casing of associated tissue. No noticeable tissue reaction was observed. Innovative geometrical architecture of the transformer for an artificial heart system is described in this article. The ferrite is utilised to build the main core and the amorphous magnetic material is used for creating the secondary core of the transformer. 20 W is adequate to operate the heat pump which can be readily transferred has been experimentally confirmed. The spacing in between the coils is usually of 5mm that gives the 90 percent transmission efficiency with 102.5 kHz switching frequency. Few features of the built transformer are described and illustrated in this article.
[1] Shankar MAR, Reddy DSK, Feisso DS. Prototype of Total Artificial Heart System. Int J Trend Sci Res Dev. 2017;
[2] Zhao L, Foo CF, Tseng KJ. A new structure transcutaneous transformer for artificial heart system. IEEE Trans Magn. 1999;
[3] Strüber M, Meyer AL, Malehsa D, Kugler C, Simon AR, Haverich A. The Current Status of Heart Transplantation and the Development of „Artificial Heart Systems“. Dtsch Aerzteblatt Online. 2009;
[4] Yambe T, Nanka SS, Shiraishi Y, Tanaka A, Yoshizawa M, Abe KI, et al. Recording Vagal Nerve Activity for the Control of an Artificial Heart System. ASAIO J. 2003;
[5] Weber S, Doi K, Massiello AL, Byerman BP, Takagaki M, Fukamachi K, et al. In vitro controllability of the MagScrew total artificial heart system. ASAIO J. 2002;
[6] Homma A, Sumikura H, Ohnuma K, Ohgoe Y, Takewa Y, Tatsumi E, et al. Development of a pneumatic ventricular assist device and a pnumatic total artificial heart system. Trans Japanese Soc Med Biol Eng. 2014;
[7] Westerhof N, Elzinga G, Sipkema P. An artificial arterial system for pumping hearts. J Appl Physiol. 1971;
[8] Snyder A, Rosenberg G, Weiss W, Pierce W, Pae W, Marlotte J, et al. Completely implantable total artificial heart system. ASAIO Trans. 1991;
[9] Pelletier B, Spiliopoulos S, Finocchiaro T, Graef F, Kuipers K, Laumen M, et al. System overview of the fully implantable destination therapy--ReinHeart-total artificial heart. Eur J Cardiothorac Surg. 2015;
[10] Beyersdorf F. Heart Transplant and Artificial Heart Systems. Dtsch Aerzteblatt Online. 2009;
SOMC, Sanskriti University, Mathura, Uttar Pradesh, India (anubhavs.somc@sanskriti.edu.in)
No. of Downloads: 20 | No. of Views: 571
D. Kabeya Nahum, Gopinath Chattopadhyay.
February 2024 - Vol 11, Issue 1
Mir Safoora Gull, Er Sakshi Bhatia, Er Ishfaq Gull.
April 2023 - Vol 10, Issue 2
Zahoor Ahmad Bhat, Mr. Ashish Kumar.
April 2023 - Vol 10, Issue 2