SU740954A1 - Cutting machine drive - Google Patents

Description

one

The invention relates to drives for cutting machines used, for example, for cutting peat during its extraction, cutting stone, etc.

Known drives peat, leading the development of peat processing stumps, containing a differential clutch and gearbox

However, such drives are difficult to operate.

A drive for stone-cutting machines is also known, which includes the electric motors of the feed drives and the cutting tool 2.

However, the speed control in such drives is accomplished with sophisticated devices with low reliability.

The aim of the invention is to simplify the device and increase its reliability.

The goal is achieved by the fact that one of the motor windings

The feed is included in the motor chain of the cutting tool.

When using an asynchronous motor with a phase-rotor as a drive for a cutting tool, one of the excitation windings of the feed motor is connected through a three-phase rectifier into the rotor circuit of the cutting tool's motor; when an asynchronous motor with a squirrel cage rotor is used as a cutting tool drive, one of the excitation windings of the feed motor is connected through a single-phase rectifier to a disconnecting stator motor through a single-phase rectifier; when using a dc electric motor as a drive of a cutting tool, one of the excitation windings of the electric motor is switched on

20 directly into the chain of the electric motor of the cutting tool.

FIG. 1 shows a cutting machine drive when an asynchronous motor with a phase rotor is used in the drive of the cutting tool drive4 | in fig. 2 - the same, with a short-circuited rotor; in fig. 3 - the same, with a constant current dual motor.

The device consists of a tool (cutter) 1, which receives rotation through a reduction gear 2 from an electric motor 3, a feed mechanism 4, which receives rotation through a reduction gear 5 from an electric motor 6 with excitation windings 7 and 8. The resistor 9 is connected in parallel to the excitation winding 8 of the feed electric motor 6, which is on to the rotor circuit of the drive motor 3 via a three-phase rectifier 1O, if an induction motor with a phase-rotor is used as the drive of the cutting tool {Fig. l); to the circuit of one phase of the stator through a single-phase rectifier 10, if an asynchronous short-circuited electric motor is used as the drive of the cutting tool (Fig. 2); directly in the uertb core of the electric motor 3, if a direct current electric motor is used as the drive of the cutting tool (Fig. 3),

The drive works as follows.

When operating on a uniform material, the rotation speed of the tool 1 is constant, the rotation speed of the feed motor 6 is also constant and is determined by the properties of the material being destroyed. The power developed by the drive by the 1st electric motor 3 is small and the current consumed by it is small. If an asynchronous motor with a phase-rotor is used as a cutting tool motor, the rotor winding current of the drive motor 3, rectified by rectifier 1O, flows through the excitation winding 8 and generates a relatively small magnetic flux. If an asynchronous short-circuited motor is used as the cutting tool motor, a stator phase current flows through the rectifier 1O and the excitation winding 8; if a direct current motor is used, a motor core 3 flows through the excitation winding 8. In this connection, the rotation speed of the electric motor 6 begins to increase to a certain limit due to the load on it, and the tool productivity increases. or in the case of a meeting with a more solid inclusion in the material) the power developed by the driving electromotor3 increases, and consequently. Consequently, the current flowing through the excitation winding 8 increases. This causes the excitation winding to create a magnetic flux 8 of the magnitude.

0 With an increase in the magnetic flux, the rotational speed of the electric motor 6 begins to decrease and the productivity inn. pattern 1 decreases. The variable resistor 9, which shunts the winding of the bulge 8, serves to adjust (adjust) the degree of feedback on the load of the driving motor 3.

The proposed drive possesses self-regulation properties, makes it possible to fully utilize the power of the engine of the working device and at the same time protect it from emergency overloads.

Claims (4)

Invention Formula 5 1. The drive of the cutting machine, which includes the motors of the feed drives and the cutting tool. This is due to the fact that, in order to simplify it and increase the reliability of operation, one of the excitation windings of the feed motor is connected to the chain of the cutting tool motor, 2. The actuator according to claim 1, characterized in that when using 5 as a drive for a cutting tool of an asynchronous motor with a phase-rotor one of the excitation windings of the feed motor is connected through a three-phase rectifier into the circuit 0 rotor electric motor cutting tool. 3. The actuator is aa.1, characterized in that when used As a drive of the cutting tool of an asynchronous motor with a short-circuited rotor, one of the excitation windings of the feed motor is connected through a single-phase rectifier to the stator phase disconnection of the cutting tool motor 0. 4. The drive according to claim 1, characterized in that, when using a direct current electric motor as the drive of the cutting tool, one of the excitation windings of the feed motor is connected directly to the core of the electric motor of the cutting tool. 574О954 6 Sources of information, 2. Halperin M.I., Abergaue V.D. taken into account in the examination. Stone cutting machines. M., GNTI 1. Copyright of the USSR Machine-Building Literature, 1964, N9412383, class E 21 C49 / 00.02.11, 70.c. 239-243. Ш1