KR200217910Y1 - Lighter ignition_ - Google Patents

Abstract

The present invention relates to an ignition device with a piezoelectric element, and guide grooves for guiding the movement of the hammer blades are formed at both edges of the lower side of the upper assembly, and the guide groove is in the initial state in which the upper assembly and the lower assembly are assembled. It is formed with a seating support surface on which the wing is seated, and a hammer blade guide groove providing a path through which the hammer blades move so that the hammer strikes the piezoelectric element during the ignition operation, and the outer surface of the upper assembly is fixed to the lower assembly. An opening window is provided on both side walls of the lower assembly to guide the movement of the hammer blade. The window is opened in a direction facing the upper assembly, and when the upper assembly and the lower assembly are combined, The slit provides a path of movement, the hammer wing moves when trying to start the ignition by pressing the lighter button Hammer wing guide straight line to set the straight path, hammer blade forward guide slope to set the inclined path so that the hammer blade moves to the center of the guide groove when the lighter button is pressed further, hammer blade after completion of ignition operation Hammer wing initial position inclination to set the inclined path to return to the initial position, and characterized in that it is formed with a locking jaw seating surface formed to catch the locking jaw, easy to manufacture and hammer during initial assembly or ignition operation Can be adjusted more smoothly.

Description

Lighter ignition

The present invention relates to an ignition device incorporating a piezoelectric element, and more particularly, to an ignition device that generates sparks by a piezoelectric element in a portable lighter which is usually used for smoking.

1 is an exploded perspective view of an ignition device using a piezoelectric element according to the prior art. Conventional ignition device is a push button 11, the spark electrode 12, the upper assembly (13) containing the piezoelectric element, the hammer (15) hitting the piezoelectric element fixed on the upper inside of the upper assembly 13, the hammer ( Hammer spring 17 for elastically supporting the lower end of the 15, return spring 16 for elastically supporting the lower end of the upper assembly 13, and the hammer 15, hammer spring 17 and the return spring ( And a subassembly 18 for receiving 16).

When the push button 11 is pressed while the upper assembly 13 and the lower assembly 18 are assembled with each other, the hammer 15 opens the window 14 of the lower assembly 18 and the groove 14 of the upper assembly 13. Moving along, the hammer 15 strikes the piezoelectric element in the upper assembly 13 and then returns to its original position by the action of the springs 16 and 17.

According to the related art, the length of the wing 15 of the hammer 15 corresponds to the length of the diagonal direction of the lower assembly 18. The lower portion of the hammer 15 is assembled when the upper assembly 13 and the lower assembly 18 are assembled. One diagonal edge portion of the subassembly 18 maintains a right angle and the other diagonal edge portion is rounded so as to fit into the assembly 18, so that the first hammer 15 is formed by the lower assembly 18. When coupled to the top, when entering the right angled corner portion and meets the window portion of the lower assembly 18, the wing portion of the hammer 15 is protruded out of the window. In addition, according to the hole shape of the lower assembly 18, the cross-sectional shape of the upper assembly 13 to be assembled therewith also has to have a right corner shape in one diagonal direction and a round shape in the other diagonal direction. do. However, manufacturing an assembly having such a shape has a problem that is more difficult than manufacturing an assembly having a simple rectangular or cylindrical shape.

The technical problem to be achieved by the present invention is to provide a lighter ignition device that can be more easily manufactured and assembled.

1 is an exploded perspective view of an ignition device using a piezoelectric element according to the prior art.

2 is an exploded perspective view of an ignition apparatus using a piezoelectric element according to the present invention.

Figure 3a is a cross-sectional view and a bottom view of the upper assembly of the ignition device according to the present invention shown in Figure 2, and Figure 3b is a plan view and a cross-sectional view of the lower assembly.

4A to 4H are views for explaining an operating state of the ignition device according to the present invention.

In order to achieve the above object, the ignition device according to the present invention,

An upper assembly including a piezoelectric element, a hammer striking the piezoelectric element, a hammer spring elastically performing vertical movement of the hammer, and a return spring elastically performing vertical movement of the upper assembly; An ignition device having a lower assembly coupled to the upper assembly is provided in,

Guide grooves for guiding the movement of the hammer blades are formed in the lower edges of both side surfaces of the upper assembly, and the guide grooves are seated on which the hammer blades are seated in an initial state in which the upper assembly and the lower assembly are assembled, and during ignition operation. It is formed of a hammer blade guide groove providing a path for the hammer blade to move the hammer to hit the piezoelectric element, the outer surface of the upper assembly is provided with a locking jaw for fixing with the lower assembly,

On both side walls of the lower assembly, an open window is formed to guide the movement of the hammer blade corresponding to the guide groove, and the window has a space through which the hammer blade passes and is opened in a direction facing the upper assembly, and the upper assembly A slit which provides the movement path of the hammer blade when the and subassemblies are combined, and extends with one inner surface of the slit, and sets the straight path of the hammer blade which sets the straight path in which the hammer blade moves when the ignition button is pressed to start ignition. When the lighter button is pressed more and more, the hammer blade is set to be inclined so that the hammer blade moves to the center of the guide groove, the induction slope of the hammer blade is connected to the end of the other inner surface of the slit, and the hammer blade is completed after the ignition operation is completed. Hammer wing initial position to set inclined path to return to initial position Slope, and is characterized in that the catching projection formed in a seating surface formed to take the locking step.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

2 is an exploded perspective view of an ignition apparatus using a piezoelectric element according to the present invention. The ignition device can be broadly divided into an upper assembly 21, a hammer 25 and a lower assembly 28. At the top of the upper assembly 21 is a lighter button (not shown) is mounted. And the hammer 25 is interposed between the upper assembly 21 and the lower assembly 28 to generate an electrical spark.

The upper assembly 21 is a shock protection plate for preventing mechanical damage due to the impact of the piezoelectric element support plate 22, the ceramic piezoelectric element 23 and the piezoelectric element 23, which generates a high voltage by the mechanical impact of the hammer 25. 24 is built into the inside.

In addition, grooves for guiding the movement of the hammer blades 251 are formed at the lower edge portions of both sides of the upper assembly 21, and the grooves have the hammer blades when the upper assembly 21 and the lower assembly 28 are assembled. 251 is supported while moving toward the guide groove of the lower assembly 28, the mounting support surface 213 and the seating side 215, and the hammer during the ignition operation to the hammer blade 251 is mounted in the initial state assembled with each other The hammer blade 251 is formed of a hammer blade guide groove 211 that provides a path for the hammer blade 251 to move so that the 25 may strike the piezoelectric element 23.

In addition, the outer surface of the upper assembly 21 is provided with a locking jaw 219 for fixing with the lower assembly 28, and also corresponding to the lower hole 29 in the lower assembly 25, the upper hole 20 This is me.

The hammer 25 includes a hammer body, a hammer blade 251 for guiding the movement of the hammer, a blow plate 254 and a hammer spring 27 that strike the impact protection plate 24 on the piezoelectric element 23 during the ignition operation. It is provided with a hammer spring coupling projection 259 to help the coupling.

The shape of the hammer blade 251 has two rounded diagonal corners 253 and 257 and the other corner 255, and the seating contact surface 255 is a seating surface of the upper assembly 21 in the initial assembly state. 213, the front induction inclined contact surface 257 is a surface in contact with the surface when the hammer blade 251 moves along the hammer blade front induction inclined surface 283 of the lower assembly 28 during the ignition operation. The initial position guide contact surface 253 is in contact with the surface when the hammer blade 251 moves along the hammer blade initial position guide slope 285 of the lower assembly 28 after the ignition operation is completed, and returns to the initial state. That's the side. Therefore, the seating contact surface 255 is formed in a substantially right angle shape so as to be stably seated on the seating support surface 213 of the upper assembly 21, the front induction inclined contact surface 257 and the initial position induction contact surface 253 is It is preferable to form the round shape so as to slide smoothly along the inclined surface.

The lower assembly 28 is coupled to the engaging protrusion 259 of the hammer 25 to elastically perform the vertical movement of the hammer spring 27, the upper assembly 21 to elastically perform the vertical movement of the hammer 25 It is provided with a return spring 26 and a spring groove (protruding in the inner bottom surface of the lower assembly 28, fixing the return spring 26 and the return spring 26) to perform.

On both side walls of the lower assembly 28, an open window 280 is formed to guide the movement of the hammer blade 251 in correspondence with the groove in the upper assembly 21, and the window 280 is formed by the upper assembly ( 21 is open to have a space corresponding to the thickness of the hammer blade 251 in the direction opposite to the hammer blade 251 can pass when the upper assembly 21 and the lower assembly 28 are initially coupled to each other. Slit 281, which provides a path, extends with one side inner surface of the slit 281, and a hammer blade induction straight line 282 which sets an inclined path in which the hammer blade 251 moves when the lighter button is about to start ignition. When the lighter button is pressed further, the hammer blade 251 moves to the center of the guide groove 211 of the upper assembly 21 so that the hammer blade front guide inclined surface 283 and the other side of the slit 281 Extends inside and completes ignition Hammer blade initial position guide inclined surface 285 for setting the inclined path to return the hammer blade 251 to the initial position, and the locking jaw seating surface 284 formed so that the locking jaw 219 of the upper assembly 21 can be caught. Is formed.

There is also a lower hole 29 corresponding to the upper hole 20 in the lower assembly 28, and these hole centers coincide at the moment of ignition, that is, at the moment when the hammer 25 hits the piezoelectric element 23. To discharge the compressed air formed in the space inside the assembly to the outside to maximize the impact energy.

3A is a cross-sectional view and a bottom view of the upper assembly 21 of the ignition device according to the present invention shown in FIG. 2, and FIG. 3B is a plan view and a cross-sectional view of the lower assembly 28. The same reference numerals are used for the same components as those shown in FIG. 2.

4A to 4H are views for explaining an operating state of the ignition device according to the present invention. 4A and 4B are views illustrating an assembling process of the upper assembly 21 and the lower assembly 28. In FIG. 4C, FIG. 4F is a view illustrating a process in which an ignition operation is performed by pressing a lighter button. Figure 4h is a view for explaining the process of returning to the initial state by releasing the lighter button after the ignition operation. Hereinafter, the operation of the ignition device will be described with reference to FIG. 4.

First, the assembling process of the upper assembly 21 and the lower assembly 28 will be described with reference to FIGS. 4A-4B.

The piezoelectric element support plate 22, the piezoelectric element 23, and the impact protection plate 24 are inserted into the upper assembly 25 and fixed in turn. Then, the hammer spring 27 and the return spring 26 are inserted into the spring groove 30 in the lower assembly 28.

The direction of the hammer blade 251 is positioned in the space direction of the slit 181 of the lower assembly 28, and then the upper assembly 21 and the lower assembly 28 are pushed together to catch the lower end of the upper assembly 21. When the jaw 219 is caught by the locking jaw seating surface 284 of the window 280 in the lower assembly 28, the upper assembly 21 and the lower assembly 28 are coupled to each other. Here, the locking jaw 219 is inclined in the advancing direction, and when the locking jaw 219 passes the inner surface of the lower assembly 28, the upper assembly 21 is bent inward by the elasticity of the plastic. Assembly 28 is spread outwards. When the locking jaw 219 passes through the inner surface of the lower assembly 28 and the end of the locking jaw 219 reaches the locking jaw seating surface 284 of the window 280, the bending phenomenon due to elasticity disappears and the locking jaw 219 is caught by the locking jaw seating surface 284. As such, the initial state in which the upper assembly 21 and the lower assembly 28 are assembled is shown in FIG. 4B.

While the engaging jaw 219 is caught by the engaging jaw seating surface 284 from the beginning of the coupling, the hammer blade 251 is in contact with the hammer blade seating support surface 213 of the upper assembly 21 and the lower assembly 28 It is supported by the seating surface 215 by the pressing force in the direction of proceeds through the slit 281 into the lower assembly 28. Then, when the locking jaw 219 is caught by the locking jaw seating surface (284), the hammer blade 251 is supported on the seating support surface 215 and no longer move upwards, and also the hammer body 25 is a hammer spring ( It is supported by the elastic force of 27 and can no longer move down, so that the hammer 25 is fixed at a fixed position.

On the other hand, the upper assembly 21 is supported by the return spring 26 in the lower assembly 28, and the hammer 25 is supported by the hammer spring 27 in the lower assembly 28 and further down It is fixed without moving. This state becomes an initial state in which the piezoelectric unit can actually operate.

Next, how the ignition operation occurs when the upper assembly 21 and the lower assembly 28 are brought into close contact with each other will be described with reference to FIGS. 4C-4F.

When the lighter button is pressed to ignite the lighter, the hammer blade 251 is supported by the seat support surface 213 and moves along the induction straight surface 282 along the forward induction slope 283, and the hammer 25 When the center reaches the center of the guide groove 211 of the upper assembly 21, the hammer contact 25 is separated from the seat receiving surface 213 while the hammer 25 is the hammer spring (27) The impact plate 254 of the hammer 25 hits the impact protection plate 24 by moving toward the guide groove 211 instantaneously by the elastic force of the. When the lighter button is released after the lighter is ignited, the hammer blade 251 moves along the initial position guide slope 285 so that the seating contact surface 255 of the hammer blade 251 is the initial seating surface of the upper assembly 21 ( 281) to be supported.

The above-described ignition process will be described in more detail as follows.

When the upper assembly 21 and the lower assembly 28 are pushed together in the initial assembly state, the hammer blade 251 is supported on the seat support surface 213 so that the side of the seat contact surface 255 is the hammer blade induction straight surface 282. Move downwards. If it continues to push each other, the front induction inclined surface 257 of the hammer blade 251 moves in contact with the hammer blade front guide inclined surface 283, so that the seating contact surface 255 of the hammer blade 251 gradually increases the upper assembly 21 ) And gradually move toward the hammer blade guide groove 211 while leaving the mounting support surface 213 of the hammer, and the body of the hammer 25 rotates while moving downward in the lower assembly 28. Proceed towards the center.

When the upper assembly 21 and the lower assembly 28 are continuously pushed together, the seating contact surface 255 of the hammer blade 251 completely detaches the seating support surface 213 of the upper assembly 21 so that the hammer 25 The body moves rapidly toward the hammer wing guide groove 211 by the elastic force of the hammer spring 27, and eventually the striking plate 254 of the hammer 25 strikes the impact protection plate 24 in contact with the piezoelectric element 23. do. When the impact plate 254 and the impact protection plate 24 of the hammer 25 collide with each other, the impact energy is transmitted to the piezoelectric element 23 to generate high voltage electricity.

The upper hole 20 on the wall of the upper assembly 21 and the lower hole 29 on the wall of the lower assembly 28 are in close contact with each other. Coincides with the upper assembly 21 and the lower assembly 28 so that compressed air is formed between the hammer 25 and the impact protection plate 24 to prevent the impact force from being attenuated. It plays a role in releasing air.

In the state in which the upper assembly 21 and the lower assembly 28 are in close contact with each other, the recovery spring 26 maintains the maximum contact state, and the hammer spring 27 maintains the maximum expansion state.

When the forces pushing the upper assembly 21 and the lower assembly 28 to each other are removed, the process returns to the initial assembled state, with reference to FIGS. 4G and H.

First, when the upper assembly is moved upward by the elastic force of the recovery spring 26, the initial position guide contact surface 253 of the hammer blade 251 is directed to the hammer tip initial position guide slope 285 of the lower assembly 28. It comes in contact with, the hammer blade 251 is supported by the hammer spring 27 to continue to move along the slope.

When the hammer blade 251 is out of the boundary of the initial position guide inclined surface 285, the seating contact surface 255 of the hammer blade 251 is caught by the hammer blade initial seating surface 213. The upper assembly 21 continues to move upward and stops moving when the locking jaw 219 reaches the locking jaw seating surface 284. At this time, the seating contact surface 255 of the hammer blade 251 is placed on the hammer blade seating support surface 213, the initial assembly state.

As described above, according to the ignition device according to the present invention, the inner shape of the upper assembly and the lower assembly is simply at right angles, and the grooves or windows provided in the upper assembly and the lower assembly are simple and easy to manufacture. In addition, the guide groove of the upper assembly and the window shape of the lower assembly can more smoothly adjust the movement of the hammer during the initial assembly or during the ignition operation.

Claims (3)

An upper assembly including a piezoelectric element, a hammer striking the piezoelectric element, a hammer spring elastically performing vertical movement of the hammer, and a return spring elastically performing vertical movement of the upper assembly; An ignition device having a lower assembly coupled to the upper assembly is provided in, Guide grooves for guiding the movement of the hammer blades are formed in the lower edges of both side surfaces of the upper assembly, and the guide grooves are seated on which the hammer blades are seated in an initial state in which the upper assembly and the lower assembly are assembled, and during ignition operation. It is formed of a hammer blade guide groove providing a path for the hammer blade to move the hammer to hit the piezoelectric element, the outer surface of the upper assembly is provided with a locking jaw for fixing with the lower assembly, On both side walls of the lower assembly, an open window is formed to guide the movement of the hammer blade corresponding to the guide groove, and the window has a space through which the hammer blade passes and is opened in a direction facing the upper assembly, and the upper assembly A slit which provides the movement path of the hammer blade when the and subassemblies are combined, and extends with one inner surface of the slit, and sets the straight path of the hammer blade which sets the straight path in which the hammer blade moves when the ignition button is pressed to start ignition. When the lighter button is pressed more and more, the hammer blade is set to be inclined so that the hammer blade moves to the center of the guide groove, the induction slope of the hammer blade is connected to the end of the other inner surface of the slit, and the hammer blade is completed after the ignition operation is completed. Hammer wing initial position to set inclined path to return to initial position Inclined surface, and an ignition device, characterized in that the seat surface is formed as a catching projection formed to take the locking step. According to claim 1, On both side wall surfaces of the upper assembly is formed a top hole of a predetermined size in the portion where the hammer strikes the piezoelectric element during ignition, and also in the lower assembly to form a lower hole corresponding to the upper hole, An ignition device which can discharge the compressed air formed in the internal space to the outside at the moment when the hammer hits the piezoelectric element. The hammer of claim 1, wherein the hammer has a hammer body, a hammer blade for guiding the movement of the hammer, a blow plate striking the piezoelectric element during the ignition operation, and a coupling protrusion for assisting the coupling with the hammer spring. In the hammer blade, the corner surface in contact with the seating surface of the guide groove in the initial assembly state is formed at a substantially right angle, the corner surface and the ignition contacted when moving along the hammer blade front induction slope of the window during the ignition operation Ignition device, characterized in that the corner surface which is in contact when moving along the induction inclined surface of the hammer blade initial position of the window when the hammer blade is returned to the initial state after the operation is completed.