On the question of secondary use of exhaust exergy in power units of vehicles and tractors

Gennady M. Krokhta; Крохта Геннадий Михайлович; Egor N. Khomchenko; Хомченко Егор Николаевич; Nikolai A. Usatykh; Усатых Николай Александрович; Alexey B. Ivannikov; Иванников Алексей Борисович

doi:10.17816/0321-4443-106855

On the question of secondary use of exhaust exergy in power units of vehicles and tractors

作者: Krokhta G.M.¹, Khomchenko E.N.¹, Usatykh N.A.¹, Ivannikov A.B.²
隶属关系:
1. Novosibirsk State Agrarian University
2. Siberian Scientific and Research Institute of Mechanization and Electrification of Agriculture
期: 卷 89, 编号 3 (2022)
页面: 197-205
栏目: Theory, designing, testing
URL: https://bakhtiniada.ru/0321-4443/article/view/125923
DOI: https://doi.org/10.17816/0321-4443-106855
ID: 125923

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BACKGROUND: Efficiency of modern internal combustion engines is no more than 40%, while the significant part of exergy, released during fuel combustion, dissipates in the environment through exhaust, coolant liquid and heated details. Meanwhile, the urgent problem of operating a tractor in low ambient temperature conditions is sustaining of optimal thermal condition for the sake of decreasing of losses, increasing of combustion efficiency and, as a consequence, increasing of operating efficiency.

AIMS: Efficiency assessment of use of the complex system of utilization of thermomechanical exergy of diesel engine exhaust. Justification of type and number of stages of exhaust exergy utilization for diesel engines of vehicles and tractors for a wide range of ambient temperatures and loading conditions.

METHODS: To accomplish given aims, theoretical and experimental studies were carried out in order to assess exhaust exergy potential in dependence on engine loading conditions and ambient temperature. Comparative studies of the D-440 and the SMD-62 engines were carried out, making it possible to assess the influence of exhaust system design features on amount of exergy losses.

RESULTS: Exhaust performance losses of the SMD-62 engine with the TKR-11N-1 turbocharger at nominal mode were 0.8. Meanwhile, maximal exhaust performance losses at idle mode are 0.92. Authors suggested the special method of analysis of certain exhaust exergy components, which allows analyzing possible ways of its secondary use. The obtained equations determine quantitative and qualitative ratios between exhaust exergy components in comparison to maximal exhaust exergy potential to be utilized.

CONCLUSIONS: Based on experimental data analysis and its statistical processing, it follows that middle powered engines have limited resources of waste heat. Theoretically, it should be enough for ensuring the turbocharger operation and sustaining of thermal condition in a gearbox and a cooling system in winter.

关键词

utilization, waste heat, exhaust, exergy, exergy potential, losses, diesel engine, recuperative heat exchanger, turbocharger

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作者简介

Gennady Krokhta

Novosibirsk State Agrarian University

编辑信件的主要联系方式.
Email: mshipo@mail.ru
ORCID iD: 0000-0001-5686-0876
SPIN 代码: 3324-4788

Professor, Dr. Sci. (Engin.), Professor of the Agricultural Machinery Department

俄罗斯联邦, Novosibirsk

Egor Khomchenko

Novosibirsk State Agrarian University

Email: mshipo@mail.ru
ORCID iD: 0000-0002-0805-9766
SPIN 代码: 2632-5221

Cand. Sci. (Engin.), Head of the Agricultural Machinery Department

俄罗斯联邦, Novosibirsk

Nikolai Usatykh

Novosibirsk State Agrarian University

Email: mshipo@mail.ru
ORCID iD: 0000-0001-8609-9627
SPIN 代码: 9542-7408

Senior Lecturer of the Agricultural Machinery Department

俄罗斯联邦, Novosibirsk

Alexey Ivannikov

Siberian Scientific and Research Institute of Mechanization and Electrification of Agriculture

Email: alekc73@rambler.ru
ORCID iD: 0000-0002-1216-0146
SPIN 代码: 2305-9701

Cand. Sci. (Engin.), Leading Researcher

俄罗斯联邦, Krasnoobsk

参考

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Mirmov NI, Mirmov IN. Absorbtsionnye kholodil’nye mashiny dlya polucheniya otritsatel’nykh temperatur okhlazhdeniya. Proceeedings of BTSU. Issue 1, Forestry, Nature Management, Processing of Renewable Resources. 2017;(2):328–341. (In Russ).
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Krokhta GM, Khomchenko EN. Eksergeticheskaya otsenka effektivnosti gazoturbinnogo nadduva traktor-nogo dvigatelya. Vestnik NGAU. 2013;(1):135–140. (In Russ).
Brodyanskii VM. Eksergeticheskii metod i perspektivy ego razvitiya. Teploenergetika. 1988;(2):14–17. (In Russ).
Krokhta GM. Osobennosti ekspluatatsii traktorov v usloviyakh nizkikh temperatur: monografiya. Novosibirsk: «Zolotoi kolos»; 2017. (In Russ).

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2. Fig. 1. The diagram of the exergy, used in the engine turbocharger.

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3. Fig. 2. Exergy coefficient of using exhaust exergy in the TKR-8.5 turbocharger for the D-440 engine operation at the full-load curve.

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4. Fig. 3. Coefficient of usage of the SMD-62 engine exhaust exergy in the TKR-11N-1 turbocharger at load characteristic for nen=2100 min-1 -х-х-х- - (toc = + 24 °C); - о - о - о- - toc = - 33 °C).

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5. Fig. 4. Maximal exhaust exergy at the turbocharger inlet, depending on the load ratio of the SMD-62 engine (nen=2100 min-1) -х-х-х- - (toc = + 24 °C); - о - о - о- - toc = - 33 °C).

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6. Fig. 5. The TKR-11N-1 turbocharger power at full load of the SMD-62 engine (nen=2100 min-1), depending on ambient temperature.

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