Design Methodology of Camshaft Driven Charge Valves for Pneumatic Engine Starts

Oil & Gas Science and Technology-revue De L Institut Francais Du Petrole Pub Date : 2012-01-01 DOI:10.2516/OGST/2013207

Michael M. Moser, Christoph Voser, C. Onder, L. Guzzella

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引用次数: 7

Abstract

Idling losses constitute a significant amount of the fuel consumption of internal combustion engines. Therefore, shutting down the engine during idling phases can improve its overall efficiency. For driver acceptance a fast restart of the engine must be guaranteed. A fast engine start can be performed using a powerful electric starter and an appropriate battery which are found in hybrid electric vehicles, for example. However, these devices involve additional cost and weight. An alternative method is to use a tank with pressurized air that can be injected directly into the cylinders to start the engine pneumatically. In this paper, pneumatic engine starts using camshaft driven charge valves are discussed. A general methodology for an air-optimal charge valve design is presented which can deal with various requirements. The proposed design methodology is based on a process model representing pneumatic engine operation. A design example for a two-cylinder engine is shown, and the resulting optimized pneumatic start is experimentally verified on a test bench engine. The engine’s idling speed of 1200 rpm can be reached within 350 ms for an initial pressure in the air tank of 10 bar. A detailed system analysis highlights the characteristics of the optimal design found.

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气动发动机启动用凸轮轴驱动充气阀设计方法

怠速损耗在内燃机的燃料消耗中占很大比例。因此，在怠速阶段关闭发动机可以提高其整体效率。为了驾驶员的接受，必须保证发动机的快速重启。一个快速的发动机启动可以使用一个强大的电动启动器和一个适当的电池，在混合动力汽车中发现，例如。然而，这些设备涉及额外的成本和重量。另一种方法是使用装有加压空气的油箱，这种空气可以直接注入气缸，以气动方式启动发动机。本文讨论了采用凸轮轴驱动充液阀启动气动发动机的问题。提出了一种能满足各种要求的空气最优充气阀设计的一般方法。所提出的设计方法是基于一个表示气动发动机运行的过程模型。最后以某双缸发动机为例进行了设计，并在某台架发动机上进行了实验验证。发动机的空转速度1200转可在350毫秒内达到初始压力在空气罐10巴。详细的系统分析突出了所发现的优化设计的特点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Oil & Gas Science and Technology-revue De L Institut Francais Du Petrole

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