RU131050U1 - ELECTROMECHANICAL HAMMER OF DIRECT ACTION - Google Patents

Abstract

A direct-action electromechanical hammer containing a stator with an excitation winding, a shock element and a casing, characterized in that the stator contains an anchor winding, and the shock element consists of a magnetic and shock parts.

Description

The technical field to which the utility model belongs.

The utility model relates to the section of construction and mining, namely, to electromagnetic devices for percussion drilling using a moving reciprocating percussion element.

The level of technology.

Closest to the utility model in technical essence is a direct-action electromechanical hammer containing a stator with an excitation winding, a shock element and a casing (see patent RU No. 2018652, published on 08.30.1995).

In the known hammer, the magnetic circuit has a significant non-magnetic part, consisting of a non-magnetic gasket between the magnetic section of the stator and the impact element and a working air gap, the size of which is comparable with the length of the stroke. This leads to a large magnetic resistance and leads to a limitation of traction and the need to increase magnetomotive force, and, consequently, an increase in the number of turns of the field winding and overuse of the winding wire. In addition, different windings are used for forward and reverse operation, which leads to inefficient use of the winding and additional over-expenditure of the winding wire.

Disclosure of a utility model.

The problem to which the claimed utility model is directed is to increase the efficiency of use of the winding and reduce the consumption of the winding wire.

The technical result consists in using the same winding for direct and reverse motion, increasing traction and reducing the number of turns of the winding.

The technical result is ensured by the following set of features: a direct-action electromechanical hammer containing a stator with an excitation winding, a shock element and a casing, characterized in that the stator contains an anchor winding, and the shock element consists of a magnetic and shock parts.

The problem to which the claimed utility model is directed, and the technical result are interconnected as follows.

The use of the same winding for direct and reverse motion, an increase in traction and a decrease in the number of turns of the winding leads to an increase in the efficiency of use of the winding and a decrease in the consumption of the winding wire.

A brief description of the drawings.

The drawing shows a direct-acting electromechanical hammer.

Implementation of a utility model.

A utility model can be implemented as follows.

In a direct-action electromechanical hammer containing a stator with an excitation winding, a shock element and a casing, the stator contains an anchor winding, and the shock element consists of a magnetic and shock parts (see drawing).

Thus, the purpose of the utility model - its use as an electromechanical hammer of direct action - is being realized.

Information confirming the possibility of obtaining a technical result during the implementation of a useful model (a causal relationship of the essential features with the specified technical result) is as follows.

Equipping the stator with an anchor winding leads to using the same winding for direct and reverse travel, increasing traction and reducing the number of turns of the winding.

Therefore, the set of essential features is sufficient to achieve the technical result provided by the utility model.

Description of the design of the device:

In a direct-action electromechanical hammer containing a stator 1 with an excitation winding 2, a shock element and a casing, the stator 1 contains an anchor winding 3, and the shock element consists of a magnetic 4 and shock 5 parts. Field winding 2 and anchor winding 3 are wound on a non-magnetic reel. The magnetic part 4 of the percussion element is located inside the bobbin. At the upper end of the magnetic part 4 of the shock element, a guide rod is inserted that enters the stop sleeve. The stop is located on the upper end of the stator 1. The reverse system is made in the form of a current direction switch for the armature winding 3 or field winding 2. An elastic pad is installed on the foot. The hammer is equipped with two or more retaining magnets or electromagnets mounted on the rods with the possibility of movement, while stops are made at the lower ends of the rods.

The hammer works as follows.

The field winding 2 creates a magnetic flux, which is localized in the stator 1, the magnetic part 4 of the shock element and the tooth zone. The magnetic flux in the working air gap interacts with the current of the armature winding 3, as a result of which, in accordance with Ampere’s law, a tractive effort arises to accelerate the shock element. When changing the current direction of the armature winding 3 or field winding 2, the direction of traction changes to the opposite and a reverse stroke is carried out. The return stroke of the shock element is extinguished by a stop with an elastic pad. In this case, an impulse is transmitted to the holding magnets or electromagnets, which move upwards along their rods, after which they lower back and are fixed in the lower position by the corresponding stops.

Thus, the proposed direct-acting electromechanical hammer increases the efficiency of using the winding and reduces the consumption of the winding wire.

The effectiveness of the proposed direct-action electromechanical hammer is determined by its improved design.

Claims (1)

A direct-action electromechanical hammer containing a stator with an excitation winding, a shock element and a casing, characterized in that the stator contains an anchor winding, and the shock element consists of a magnetic and shock parts.

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