SU544798A2 - A mechanism for converting reciprocating motion into rotational - Google Patents

Description

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The invention relates to mechanical engineering, namely, mechanisms for converting reciprocating motion into rotary motion, can be used in internal combustion engines, and is an improvement of the known auth mechanism. St. No. 449192.

Mechanisms are known for converting a reciprocating movement into a rotary motion, comprising a drive link with a screw groove on the inner surface and a driven link in the form of a shaft, on the surface of which a pin is interconnected with the groove 1.

A disadvantage of the known mechanisms is the presence of a shock at the moment of a change in the direction of the twin pusher.

According to the main author. St. No. 449192, a mechanism is known for converting a reciprocating movement into a rotary motion, comprising a drive link with a screw groove on the inner surface and a driven link in the form of a shaft, on the surface of which a pin interacting with the groove is installed, the driving link being made in the form of two semi-cylinders, screw grooves which are a continuation of one another at the extreme positions of one half-cylinder relative to the other as they move in the opposite direction 2.

A disadvantage of the known mechanism is the presence of "dead positions of the shaft pivot at the moment of its transition from the groove of one semi-cylinder to the groove of the other semi-cylinder during their interaction.

The aim of the invention is to improve the dynamic characteristics of the mechanism and eliminate the "dead stroke."

This is achieved by the fact that on the inner surfaces of each half-cylinder there are at least one additional screw slot, which are continued: they are each other in the extreme positions of the half-cylinders and equidistant to the main grooves, and the mechanism is provided with additional pins mounted on shaft with angular displacement and interacting with additional screw grooves.

The drawing shows the proposed mechanism, a general view.

The mechanism contains a driving link 1, made in the form of two semi-cylinders 2 and 3, on the inner surface of which screw grooves 4 and 5 are made, which are a continuation of one another in the extreme positions of semi-cylinders 2 and 3, and additional screw grooves 6 and 7, which continuation of one another in the extreme fields of semi-cylinders and equidistant to the main screw grooves 4 and 5, the slave link, made in the form of a shaft 8, on the outer surface of which the main 9 and additional 10 pins are installed, each of which interacts respectively with the main 4 and 5 and additional 6 and 7 screw slots. At the end of one of the grooves (Naz 4) made expansion 11.

The mechanism works in the following way.

The half cylinders 2 and 3 of the driving link 1 are moved along the shaft axis in the opposite direction relative to each other. Screw grooves 4 and 5, interacting with pin 9, and additional screw grooves 6 and 7, with additional pin 10, drive shaft 8 into rotational motion.

In the extreme positions of the semi-cylinders 2 and 3, the screw grooves of one semi-cylinder are an extension of the screw grooves of the other semi-cylinder. At this moment, the pin 10 is in the "dead position", while the pin 9 is in the groove 4 of the half-cylinder 2 under load.

When the pin 10 passes the “dead polishing,” the semi-cylinders reverse. The pin 10 will be under load of the additional groove 7 of the half-cylinder 3, and the pin 9 will be in free movement through the slot expansion 11 before it enters the groove 5 of the half-cylinder 3.

Claims (2)

1. Kozhevnikov S. N. and others. Mechanisms. M., Mechanical Engineering, 1965, p. 350 2. Avt. St. N ° 449192, cl. F 16H, 1972 (prototype).