RU2077988C1 - Engraving electric hammer - Google Patents

Abstract

FIELD: ENGRAVING electric hammer designs. SUBSTANCE: electric hammer yoke has additional central rod and tail end and is mounted with side rods capability to be engaged with longitudinal grooves on inner surface of body. Core of armature is made in the form of rectangular parallelepiped and is mounted in groove of handle and core is spring-loaded by two springs. EFFECT: improved design. 3 dwg

Description

 The invention relates to devices for artistic and decorative processing of products, mainly made of stone or a material similar in hardness, and can be used to apply images (for example, portraits or drawings), recessed into the surface of the processed material, on granite or similar monuments in the field of funeral services , in construction and architecture in the design of both building facades and interior decoration, decoration of the interiors of rooms finished with stone or other solid materials, e.g. metal action.

 The invention can be used in the workshops of sculptors and designers, for example, for surface treatment or for minting, in industry for marking.

 A device is known for artistic and decorative surface treatment of a material, comprising a body, a spring-loaded striker, in the back of which a striker rests, pressed against the striker by a spring, which, in turn, is pressed by the shank (ed. St. USSR N 859 233, class B 44 B 3/00, 1980).

 In the known device for imparting the striker to the reciprocating motion, a rotary electric drive equipped with an eccentric with a rod made in the form of a string in a flexible sleeve is used. At one end, the string is fixed to an eccentric mounted on the electric drive shaft, and to the hammer on the other. A flexible sleeve is fixed at one end to the drive frame.

 The disadvantages of the known device are the complexity of its design and, as a consequence, the high cost and low reliability, as well as difficulties in handling the tool due to the significant mass. All these disadvantages are due to the principle circuit of the drive of the known device, because to give the striker a reciprocating motion, first a rotational movement is obtained by means of an electric motor, and then, using an additional conversion mechanism from the eccentric, string and flexible sleeve, the reciprocating movement of the striker is obtained. Such multi-stage obtaining of the required trajectory of the striker leads to the complexity of the known design, and its implementation in practice requires massive parts and entails difficulties in handling the tool.

 The closest to the invention in technical essence is an engraving electric hammer with a direct-acting reciprocating electric drive, in the housing of which there is an excitation winding divided into two sections, each section containing a horseshoe-shaped yoke and an anchor core, a return anchor spring, an armature vibration amplitude regulator, consisting of from a handle and a cylinder rigidly fixed in the cylinder body, a squeezing spring mounted on the cylinder between the cylinder and the handle, and a rod on which between ulkoy and a handle installed anchor return spring, this rod being rigidly connected to the striker disposed outside the body (US patent N 2467083, cl. 81 52.3, 1949).

 The known engraving electric hammer has a pear-shaped body, the elongated part of the body having a smaller diameter serves as a handle, and the expanding part of the body (larger diameter) serves to accommodate a vibrating electromagnetic pathogen. A cylinder is rigidly fixed in the handle, to which a horseshoe-shaped core is rigidly attached, on each of the rods of which one of the sections of the field winding is placed so that it partially surrounds the yoke, and partially the horseshoe-shaped core, which together with the thrust and striker armature of the mentioned vibration exciter. A spring is mounted on the armature link between the support sleeve and the handle. In the regulator of the amplitude of oscillation of the armature, the handle with the help of a threaded connection is fastened to the previously mentioned cylinder, rigidly fixed in the housing, namely in the handle. The firing pin is anchored with a collet clamp.

 The disadvantages of the known prototype device are low reliability, small amplitude and impact power of the striker, significant noise generated during operation of the tool.

 The causes of these disadvantages are the following design features of the prototype.

 The reason for the low reliability of the known device is the shock mode of operation of the collet clamp. So, during the work of the engraving hammer during vibrations of the anchor and the striker, the collet makes deletions along the handle of the amplitude regulator of the oscillations of the armature with the same frequency as the anchor. This leads to a quick failure of the collet clamp, which requires replacement and is the cause of low reliability.

 The reason for the small amplitude and impact power of the striker is the proposed scheme for the formation of a working gap between the core of the armature and the yoke, in accordance with which the working gap is formed as a result of the simultaneous action of two factors. On the one hand, such a factor is the compression of the return spring, which contributes to an increase in the gap, and on the other hand, the presence of a limiter, the role of which is the direct contact of the striker collet and the arm of the armature amplitude regulator, which prevents the increase of the working gap in this direction of the armature movement.

 Thus, the anchor does not make a complete free oscillation in both directions relative to its initial position. At the same time, the action of a compressing return spring interferes with the unobstructed movement in the direction of decreasing the working gap. With the reverse stroke in the direction of increasing the working gap, the anchor can only advance to its initial position, since its further movement is prevented by the contact of the collet and the control knob with each other. This explains the small amplitudes and impact power of the striker.

 The shock mode of operation of the collet and the handle is a source of significant noise arising from the operation of the known device, especially at idle.

 The objectives of the invention increase the reliability of the device, expanding the capabilities of the device in terms of processing depth and productivity, improving working conditions, simplifying the design.

 When solving these problems, the following technical result is achieved.

 To increase reliability, collisions of parts against each other are excluded and the design of the suspension of the anchor is changed.

 To expand the capabilities of the device, the amplitude and impact power of the hammer are increased due to the proposed design of the anchor suspension using two springs, due to which the anchor is mounted in a neutral position and can oscillate relative to it with the same amplitude in both directions along the axis of the device, while otherwise the oscillation amplitude control anchors and brisk. The rotation of the control knob forces the yoke to be displaced along the axis of the device, and the interaction of the lateral rods of a rectangular yoke with the corresponding grooves on the inner surface of the housing eliminates the rotation of the armature around the axis of the device. So, due to the displacement of the yoke relative to the core of the armature, the working gap changes, and with it the amplitude of oscillations of the armature and tip is regulated.

 To improve working conditions, the noise created during operation of the device is reduced by eliminating the collision of the device parts against each other.

 All of the above can be achieved using the engraving electric hammer of the proposed design.

 The engraving electric hammer contains a housing with an exciter located inside, through a rod connected to an external striker, and an armature oscillation amplitude regulator. In this case, the vibration exciter is equipped with a horseshoe-shaped yoke with an excitation winding and a spring-loaded armature, the core of which is connected to the rod. The armature oscillation amplitude regulator has a handle and a squeezing spring. These are similar common essential features of the prototype and the proposed solution.

 The similar frequency characteristics of the present invention and the prototype include the execution of a pear-shaped body in such a way that the elongated part of the body having a smaller diameter serves as a handle, and the expanding part of the larger diameter serves to accommodate the vibration exciter. excitation of vibration exciter.

 The distinguishing features of the proposed technical solution include the presence of additional casing and support bushings and a thrust washer, the execution of the yoke with an additional central rod, which turns it from a horseshoe-shaped into a U-shaped, and an additional central shank located opposite the additional central rod on the other side of the connecting rod the yoke and the placement of the yoke in the housing in such a way that allows the interaction of the side rods with the longitudinal grooves on the inside the front surface of the hull, performing springing of the armature by means of two springs, which are placed on the rod on both sides of the housing bushing between this sleeve and the supporting washer and supporting sleeve, performing an amplitude control of the armature oscillations so that the handle of the regulator is connected by a thread to the yoke shaft, and the squeezing spring mounted on the shank between the body and the yoke.

 These are the general distinguishing features of the proposed technical solution.

 The distinctive features of the invention should also include the implementation of the yoke rods with rectangles in cross section and the execution of the core of the armature in the form of a rectangular parallelepiped, as well as the installation of the latter in the groove of the handle of the housing.

 There is the following causal relationship between the essential features of the invention and the achieved technical result.

 Improving reliability is ensured, firstly, by eliminating collisions, i.e. due to the direct rigid connection of the core of the anchor through the draft with the striker, fixing the core of the anchor in neutral position by two springs, placing these springs on the rod on both sides of the body sleeve between this sleeve and the supporting washer and the supporting sleeve. The introduction of the above features also reduces the noise generated by the operation of the device, which improves working conditions.

 Secondly, increasing the reliability of the device is ensured by eliminating the possible influence of distortions and jamming due to the external (with respect to the excitation coil) placement of the armature core, suspension of the rod through two springs, which mutually compensate for their action and eliminate the friction of the rod against the housing sleeve, and also due to the presence of a single unit of traction friction on the end sleeve.

 The expansion of the device’s capabilities in terms of processing depth is provided by an increase in the amplitude and power of the impact due to the symmetrical suspension of the armature in the neutral position by means of two springs, a housing and support bushings and a support washer, and also due to the introduction of an additional central shank connected by a thread to the regulator handle and serving as an attachment squeezing spring, and the placement of the yoke in the housing with the possibility of interaction of the side rods with longitudinal grooves on the inner surface of the housing.

 Simplification of the design of the device is provided due to the following essential features of the proposed technical solution. Such signs are the execution of the yoke with an additional central rod, the execution of the yoke rods rectangular in cross section and the execution of the armature core in the form of a rectangular parallelepiped installed in the groove of the handle of the body with a gap, and also the design of the armature amplitude amplitude regulator is proposed.

 Moreover, the proposed U-shaped execution of the yoke allows the use of a single-section excitation coil, in contrast to the prototype, where a special two-section coil with identical section parameters is required, because otherwise the asymmetry of the magnetic circuit will cause a decrease in reliability due to distortions and jamming and a decrease in the amplitude of the impact in the process of work due to the weakest in comparison with the calculated attraction of the anchor. The implementation of the regulator of the amplitude of the oscillations of the armature is simple due to the fact that the handle slides freely relative to the body (and is not connected with it by a thread, as in the prototype). Only the handle pin is provided with thread, which is a technologically simple assembly unit.

 In FIG. 1 shows the design of an engraving electric hammer in a longitudinal section by the frontal plane; in FIG. 2 is a transverse section AA in FIG. one; in FIG. 3 is a cross-sectional view of BB in FIG. one.

 The engraving electric hammer is equipped with a housing 1, which serves to place structural elements in it and protect them from external influences. In the grooves 2 of the rectangular cross section of the housing 1 with a gap to reduce jamming and friction, lateral rectangular rods 3 of the yoke of the vibration exciter are placed. The presence of the grooves 2 provides the necessary orientation of the side rods 3 when they are moved in the process of adjusting the amplitude of the impact. An excitation coil 5 is mounted on the central rectangular rod 4 of the yoke. There is also a shank 6 on the yoke. The handle of the armature amplitude adjustment knob consists of elements such as stud 7, screw 8 and handle 9, and stud 7 is secured to the yoke shank 6 with a threaded connection. and the handle 9 is mounted on the pin 7 with a screw 8. Between the rear wall of the housing 1 and the yoke on the pin 7 and the shank 6 of the yoke is installed squeezing spring 10, which is part of the regulator of the amplitude of vibration of the armature. The screws 11 are fastened in the housing 1, the housing handle 12, ending in an end sleeve 13, supporting, along with two (first and second) anchor springs 15 and 14, the armature rod 16. The body handle 12, which is part of the housing 1, serves to hold the engraving electric hammer in the hand during operation, and the end sleeve 13 is a guide for creating the reciprocating movement of the arm 16 of the armature and is made of material providing as little friction as possible, as it is an element of a single friction pair "anchor-body" of the whole mechanism. The first anchor spring 15 is installed between the support washer 17 and the housing sleeve 18, and the second anchor spring 14 between the housing sleeve 18 and the support sleeve 19. The housing sleeve 18 is rigidly fixed to the handle 12 with screws 20, and the support sleeve 19 is rigidly fixed to the rod 16 the anchors with a cotter pin 21. The core 22 of the anchor is rigidly fixed to the rod 16 of the anchor, into which the tip 23 (striker) is inserted, held by a latch 24, which can be used as a collet clamp or screw plug with corresponding holes, which ensures the need for easy replacement of the tip 23. The excitation coil 5 is equipped with an electric cord 25 for connection to an AC network. It is preferable to use a half-wave rectifier in the electrical wiring of the electric hammer (for example, in the form of a diode installed in the electric hammer switch), which significantly increases the impact force of the electric hammer.

 The handle 9 of the regulator of the amplitude of the oscillations of the armature can be graduated in linear measures of the gap between the core 22 and the ends of the rods 3 and 4 of the yoke interacting with it or in arbitrary units. To do this, around the circumference of the handle 9 can be applied to the division for counting relative to a fixed mark on the housing 1.

 It should be noted a number of design features of the proposed design. The squeezing spring 10 on the one hand squeezes the yoke from the rear wall of the housing 1 when the stud 7 is turned out, and on the other hand prevents the stud 7 from being unscrewed from the shank 6. The support washer 17, the housing sleeve 18 and the support sleeve 19 ensure that the anchor springs 14 and 15 are fixed in such a way so that the thrust 16 under no circumstances comes into contact with the inner surface of the housing sleeve 18, thereby eliminating possible friction and jamming in this site. The core 22 of the anchor is made in the form of manufacturability of a simple rectangular parallelepiped in manufacture and is installed in the cavity of the corresponding shape of the body handle 12 with a gap, which ensures the necessary orientation of this core relative to the yoke and low probability of jamming and friction with the body 1.

 Engraving electric hammer works as follows.

 When the electric cord 25 is connected to an alternating current network, a magnetic field is generated in the excitation coil 5, which is distributed across the yoke rods 3 and 4 and closes on the armature core 22, so that the core 22 is attracted to the excitation coil 5, overcoming the resulting elastic force of the anchor springs 14 and 15. With a decrease in the instantaneous current value under the action of the resulting force from the compressed springs 14 and 15, the armature moves in the opposite direction. The described process is repeated for each half-cycle of the change in the supply alternating current, i.e. 100 vibrations in one second at a current frequency of 50 Hz.

 If the electric hammer is powered by a half-wave rectified current, then the device operates in a similar way, but the number of vibrations of the striker is 50 per second at a current frequency of 50 Hz in the network. In this case, an increase in the current in the excitation coil 5 causes an increase in the magnetic field both in the armature rods and in the armature core 22, due to which the armature is attracted to the yoke. The required direction of movement of the armature core 22 is determined by the orienting effect of the groove in which the armature core 22 is located in the handle 12 of the housing 1. Due to the rigid connection of all the armature element, the rod 16 moves together with the core 22, entraining the tip 23. The first anchor spring 15 is compressed. traction 16 continues until the force of attraction of the core 22 of the anchor to the free ends of the rods 3 and 4 of the yoke is not equal to the resulting elastic force of the two anchor springs 14 and 15 (if we neglect the inertial mass of the armature and athame friction).

 The maximum approach of the core 22 of the armature with the free ends of the rods 3 and 4 of the yoke, i.e., the minimum gap at a given position of the yoke) is carried out at the amplitude value of the current in the excitation coil 5. Subsequently, when the current strength in this coil decreases from amplitude to zero, accordingly, a decrease in the force of attraction of the core 22 of the anchor to the yoke, as a result of which the core 22, the rod 16 and the tip 23 under the action of the resulting elastic force of the springs 14 and 15 move towards the material being processed until they collide the latest changes with the tip 23. In this case, the straightening of the first anchor spring 15 is accompanied by the process of simultaneously compressing the anchor spring 14. During this half-period of current, when there is no current, the armature moves by inertia.

 The proposed engraving electric hammer has such advantages as increased reliability, great opportunities for processing depth and productivity, better working conditions for staff, simple design.

Claims (1)

 An engraving electric hammer comprising a housing with a vibration exciter located inside, provided with a horseshoe-shaped yoke with an excitation winding and a spring-loaded armature, the core of which is connected via a rod to the striker, and an armature vibration amplitude regulator equipped with a handle and a release spring, characterized in that the yoke is provided with an additional central shaft and shank and installed with the possibility of interaction of the side rods with longitudinal grooves on the inner surface of the housing, the core of the armature is made in the form e is a rectangular parallelepiped and is installed in the groove of the handle, the anchor is spring-loaded with two springs placed on the rod on both sides of the body sleeve between the support washer and the support sleeve, the handle of the armature vibration amplitude adjustment knob is connected by a thread to the yoke shaft, on which a release spring is installed between the body and the yoke.

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