KR102187573B1 - Electronic hammer - Google Patents

Abstract

The present invention relates to an electronic hammer. An objective of the present invention is to provide an electronic hammer which effectively transfers vibration of a core unit to a base by forming the shape of the base to correspond to the shape of the core unit. According to a proper embodiment of the present invention, the electronic hammer (3) strikes a base (160) and, as shown in Figure 5, comprises: a steel plate means (100) coupled to the base (160) and provided with a tap/hole machined thereon; a pin means (143) fastened to the hole; and an electromagnet means (15) coupled to the pin means (143) to push and pull the steel plate means (100). The present invention effectively transfers vibration of the core unit to the base to extend the life of the electronic hammer and improve vibration properties.

Description

Electronic hammer {ELECTRONIC HAMMER}

The present invention relates to an electronic hammer, and more particularly, to an electronic hammer that uniformly transmits the vibration of the core to the base by spring coupling corresponding to the shape of the core.

The powder conveying facility has a silo for storing material, and an electronic hammer is installed in the silo so that the material stored in the silo is discharged through the outlet. The electronic hammer is installed in the powder transfer facility and operates so that the material stored in the silo is discharged smoothly through the discharge port. Prior literature of the electronic hammer includes the following technologies.

Prior Document Publication No. 10-2014-0064559 The pulsating wave driving device for an electronic hammer of the powder conveying facility is a pulsation and a transducer 100 installed in the outlet 3 as shown in FIG. 200) to output the material through the outlet (3).

Prior Document Registration No. 10-1964558 Scale removal electronic hammer device, as shown in Figure 2, the blade plate 440 to which the core portion 430 is coupled is spring-coupled by the spring portion 450 to support the frame ( It is supported by 420 and transmits vibration to the base 410.

The conventional electronic hammer embeds an I-type core in the base 410 and operates so that the electromagnetic force of the core part 430 affects the I-type core so that the vibration of the core part 430 is transmitted to the base 410. Accordingly, the conventional electronic hammer has a problem in that the I-type core corresponding to the E-type core of the core portion 430 is configured in the base 410, so that the number of parts is greater than that of the present invention, and the structure is complex.

In addition, in the conventional electronic hammer, the base 410 and the blade plate 440 do not correspond to the shape of the E-type core, and have a circular shape, so that the vibration of the square-shaped core part 430 is smoothly transmitted to the base 410. There is a problem that cannot be done.

Publication No. 10-2014-0064559 Pulsating wave drive device for electronic hammer of powder transfer facility Registration No. 10-1964558 Scale removal electronic hammer device

Conventional electronic hammers do not smoothly transmit the vibration of the square-shaped core part to the base because the base and the wing plate have a circular shape, but the present invention forms a base shape corresponding to the shape of the core part to smoothly transmit the vibration of the core part to the base It is an object of the present invention to provide an electronic hammer.

In addition, an object of the present invention is to provide an electronic hammer that does not constitute an I-type core in the base, but constitutes the base as a steel plate means, and the E-type core of the core part exerts an electromagnetic force on the steel plate means to generate vibration.

In the electronic hammer (3) striking the base 160 according to a preferred embodiment of the present invention, as shown in Figure 5, the tab / hole-processed steel plate means 100 coupled to the base 160 ; Pin means (143) fastened to the hole; And an electromagnet means 15 that is coupled to the pin means 143 to push and pull the iron plate means 100.

In addition, the holes are drilled in a square two-row three-row arrangement, and the pin means 143 is coupled to a square two-row three-row arrangement.

In addition, the electromagnet means (15), the E-shaped core 150 is wound; And a plurality of springs 141 that are fitted in the pin means 143 for supporting the E-shaped core 150 and are placed vertically on the support plate of the E-shaped core 150 and have the same elastic modulus. It is characterized.

In addition, the steel plate means 100 is characterized in that it includes a curved surface 120 facing each other at an edge and a parallel straight surface 110 connecting the corners of the curved surface.

In addition, the number of springs 141 is characterized in that the elastic modulus is equal to 12.

In addition, the E-type core 150 is characterized in that it comprises a striking protrusion for hitting the iron plate means 100 at both ends of the bottom surface.

In addition, the electromagnet means 15 is characterized in that the coil 10 is closed with an insulating tape.

In the present invention, the vibration of the core portion is smoothly transmitted to the base, thereby extending the life of the electronic hammer and improving the vibration characteristics.

1 is an exemplary view of a pulsating wave driving device for an electronic hammer of a conventional powder transfer facility.
2 is an exemplary view of a conventional scale removal electronic hammer device.
3 is an exemplary view showing a facility in which an electronic hammer is used.
4 is an exemplary diagram of a controller that controls an electronic hammer.
5 is an exemplary diagram of an electronic hammer.
6 is an exploded view of the electronic hammer.

Hereinafter, an electronic hammer according to an embodiment of the present invention will be described in detail with reference to the drawings. Hereinafter, descriptions of conventionally known matters are omitted or simplified to clarify the subject matter of the present invention.

3 is an exemplary view showing a facility in which an electronic hammer is used.

The facility includes a hopper or silo (1) for storing material; A level meter 2 for measuring the level of the material stored in the silo 1; An electronic hammer (3) installed at the exit side of the silo (1) to apply a blow to the silo (1); A feeder 4 for conveying the material discharged from the outlet of the silo 1 to the conveyor 5; And a conveyor 5 for transferring the material conveyed by the feeder 4 to a destination.

The electronic hammer 3 is installed at the outlet side of the silo 1 and strikes the silo 1 so that the material stored in the silo 1 is discharged smoothly through the outlet. The electronic hammer 3 is controlled by the controller 50, and the controller 50 controls the power supply to the electromagnet coil 10 constituting the electronic hammer 3 so that the blow output by the electronic hammer 3 is To be delivered to the silo (1) The controller 50 controls the supply of power to the electromagnet coil 10 by adjusting the voltage or frequency, and the vibration intensity or frequency of the electronic hammer 3 varies according to the voltage or frequency. Since the frequency driven by the controller 50 is within the resonant frequency range of the coil, heat generated from the coil may be reduced. Frequency driving beyond the resonant frequency of the coil may generate heat in the coil and should be avoided.

4 is an exemplary diagram of a controller that controls an electronic hammer.

The electronic hammer 3 includes an electronic hammer 3 for hitting the silo 1 and including a coil 10 for generating an electromagnetic force; A driver 20 for driving the coil 10 of the electronic hammer 3; SMPS for supplying power to the driver 20; And a controller 50 for controlling the voltage circuit 30 and the frequency circuit 40 of the SMPS.

The driver 20 drives the coil 10 of the electronic hammer 3 to PWM (Pulse Width Modulation). PWM driving of the driver 20 drives the coil 10 of the electronic hammer 3 by generating a driving waveform by pulse width modulation.

The controller 50 uses an SMPS that receives commercial power and outputs a voltage lower than the commercial power or a voltage higher than the commercial power. SMPS operates in a buck mode when outputting a lower voltage than a commercial power supply, and operates in a boost mode when outputting a higher voltage than a commercial power supply.

The controller 50 increases or decreases the voltage or frequency. The controller 50 may use an acceleration/deceleration table while controlling an increase or decrease in voltage or frequency. The acceleration/deceleration table stores a time value corresponding to acceleration from stop to a constant speed or acceleration from a constant speed to another constant speed, and the controller 50 increases or decreases the voltage or frequency using the time value stored in the acceleration/deceleration table. do. When acceleration is applied from a constant speed included in the acceleration/deceleration table to another constant speed, the controller 50 may reach the target vibration intensity or target frequency within a shorter time. The smooth start and smooth stop are the characteristics that the electronic hammer 3 should have, and the silo 1 is not subjected to a sudden impact, so the durability of the silo 1 can be increased.

5 is an exemplary diagram of an electronic hammer.

The electronic hammer 3 is surrounded by a parallel straight surface 110 connecting the curved surface 120 and the curved surface 120 facing the rim, and the tab/hole-processed iron plate means 100; A pin 143 coupled to the iron plate means 100; A core bracket 170 supported by a pin 143; And an E-shaped core 150 coupled to the core bracket 170 and wound around the coil.

The design of the electronic hammer 3 and the controller 50 can be changed according to various requirements of the silo 1 in which the electronic hammer 3 is installed, and the vibration intensity applied to the silo 1. The controller 50 driving the E-shaped core 150 of the electronic hammer 3 can change the voltage or frequency of the driving power supply, thereby satisfying the conditions required by the installation structure of the electronic hammer 3.

The iron plate means 100 is made of an iron-containing material that is easy to tap/hole processing while having magnetic properties, and may be steel SS400.

The steel plate means 100 is a base 160 welded on the surface of the silo 1 is fastened to the steel plate fastener 130 drilled at a predetermined distance apart from the curved surface 120 and the parallel straight surface 110, and the electronic hammer ( 3) provides a support means to which it is joined. The steel plate means 100 prevents distortion of the silo 1 when the vibration generated by the E-shaped core 150 including the curved surface 120 and the parallel straight surface 110 is transmitted to the silo 1. The parallel straight surface 110 corresponds to the square shape of the E-shaped core 150 so that the vibration of the E-shaped core 150 is smoothly transmitted to the silo 1, and the curved surface 120 is formed of the E-shaped core 150. When vibration is transmitted to the silo (1), it serves to hold the silo (1) to prevent distortion. In another embodiment, the steel plate means 100 may transmit vibration generated by the E-shaped core 150 including a circular surface to the silo 10 in a circular waveform.

A pin 143 is spring-coupled to the core fastener 142 processed in a two-row and three-row arrangement on the core bracket 170 so that the E-type core 150 coupled to the core bracket 170 is provided with the iron plate means 100. When the pull is removed, the spring 141 coupled to the pin 143 provides a restoring force. As the pulling and restoration are repeated, the striking protrusion of the E-shaped core 150 strikes the steel plate means 100 so that the vibration is transmitted to the silo 1.

The core fastener 142 of the core bracket 170 is processed in a two-row and three-row arrangement corresponding to the square shape of the E-type core 150, and the iron plate means 100 is a pin coupled to the core fastener 142 It is spring-coupled by 143. The core fasteners 142 arranged in two rows and three columns are evenly arranged to correspond to a square surface to support the E-shaped core 150. The vibration caused by the vibration generated by the square-shaped E-shaped core 150 is smoothly generated.

A plurality of springs 141 coupled to the pin means 143 support the E-shaped core 15 and have the same elastic modulus while being placed up and down on the core bracket 170 of the E-shaped core 150. The same elastic modulus of the spring 141 is attracted by the spring 141 being compressed and coupled to the pin means 143, and the power supply by the controller is cut off after the E-type core 150 is pulled. When this disappears, the restoring force is evenly transmitted to the spring 141. The plurality of springs 141 are composed of the same constant and are replaced with springs 141 of the same constant when the electronic hammer 3 is repaired, so that maintenance is easy.

The E-shaped core 150 is disposed to be spaced apart from the steel plate means 100 within 3 mm so as to smoothly pull the steel plate means 100. Since the electromagnetic force generated by the E-type core 150 is reduced by three times the distance, the E-type core 150 must be placed within 3 mm so that the force that the E-type core 150 pulls and strikes the steel plate means 100 is maximum It can be delivered with efficiency.

6 is an exploded view of the electronic hammer.

The electronic hammer includes a base 160 that is welded to the silo 1, and the base 160 has a base fastener 131 to which the steel plate means 100 of the electronic hammer 3 is coupled.

The electronic hammer 3 includes a base 160 welded to the silo 1; Steel plate means 100 coupled to the base fastener 131 of the base 160; And an E-type core 150 spring-coupled to the iron plate means 100.

The E-type core 150 is firmly coupled to the core bracket 170 by welding means, and the electromagnetic force generated by supplying electricity to the coil of the E-type core 150 acts on the steel plate means 100, and the core bracket 170 It is spring-coupled to the iron plate means 100 so that an elastic force acts, and the E-shaped core 150 hits the iron plate means 100.

The steel plate means 100 includes a border surrounded by a parallel straight surface 110 connecting the curved surface 120 and the curved surface 120 facing each other; A steel plate fastener 130 that is drilled at a predetermined distance apart from the curved surface 120 and the parallel straight surface 110 and is coupled to the base fastener 131 of the base 160; And a pin fastener 140 to which the pin means 143 is fastened so that the E-type core 150 is spring-coupled.

The core bracket 170 spring-coupled to the pin means 143 includes a core fastener 142 spring-coupled to the pin fastener 140 of the iron plate means 100; And an E-type core 150 supported by the core bracket 170 and generating an electromagnetic force. As for the electromagnet means of the E-type core 150, the coil is closed with an insulating tape.

The base 160 includes a horizontal frame 161 that is horizontally welded to and fixed to the silo; And a vertical frame 162 that is vertically welded to and fixed to the silo. The horizontal frame 161 and the vertical frame 162 of the base 160 firmly couple the base 160 to the silo 1 so that the electronic hammer 3 transmits vibration to the silo 1 and the base 160 is Hold it horizontally and vertically to avoid distortion.

The present invention is not limited to the specific preferred embodiments described above, and anyone of ordinary skill in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications Of course, such changes are within the scope of the claims.

1: silo
2: level meter
3: electronic hammer
10: coil
15: electromagnet means
20: driver
30: voltage circuit
40: frequency circuit
50: controller
100: iron plate
110: parallel straight plane
120: curved surface
130: steel plate fastener
131: base fastener
140: pin fastener
141: spring
142: core fastener
143: pin
150: E-type core
160: base
161: horizontal frame
162: vertical frame
170: core bracket

Claims (7)

In the electronic hammer 3 hitting the base 160,
A tab or hole-processed iron plate unit 100 coupled to the base 160;
Pin means (143) fastened to the hole;
Including; an electromagnet means (15) coupled to the pin means (143) to push and pull the iron plate means (100),
The electromagnet means 15 includes an E-shaped core 150 on which the coil 10 is wound; And twelve springs 141 having the same elastic modulus while being fitted in the pin means 143 for supporting the E-shaped core 150 and being placed up and down on the support plate of the E-shaped core 150. The E-type core 150 further includes a striking protrusion for hitting the iron plate means 100 at both ends of the bottom surface,
A driver (20) for driving the coil (10) of the electromagnet means (15); SMPS for supplying power to the driver 20; And
A controller 50 for controlling the voltage circuit 30 and the frequency circuit 40 of the SMPS; further includes,
The acceleration/deceleration table stores time values corresponding to acceleration from stop to constant speed or acceleration from constant speed to other constant speed,
The controller 50 is an electronic hammer, characterized in that the increase or decrease in voltage or frequency using a time value stored in the acceleration/deceleration table. The method of claim 1,
The holes are drilled in a square arrangement of 2 rows and 3 columns, and the pin means (143) is coupled to the holes of a square arrangement of 2 rows and 3 columns. delete The method of claim 1,
The iron plate means 100,
Electronic hammer, characterized in that it comprises a curved surface (120) facing each other at the edge and a parallel straight surface (110) connecting the corners of the curved surface. delete delete The method of claim 1,
The electromagnet means 15,
Electronic hammer, characterized in that the coil 10 is closed with an insulating tape.

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