KR20110038786A - Air knocker - Google Patents

Abstract

PURPOSE: An air knocker is provided to remove the need of a compression spring by employing a magnetic piston return device installed on the exterior of a cylinder. CONSTITUTION: An air knocker comprises a cylinder(11) in which a magnetic piston(12) is embedded, a cylinder head(13) which is coupled to the top of the cylinder and has an air inlet(13a) for allowing or blocking the inflow of compressed air under the control of a solenoid valve, a fixing plate(15) which is arranged in the upper side of the cylinder, an under piston(16) which is arranged in the lower side of the cylinder, and an air knocker and magnetic piston return device(20) which returns the magnetic piston having hit the under piston back to the original position to contact the fixing plate.

Description

Air knocker

The present invention is a rat hole phenomenon to prevent the attachment of the granules on the inner wall surface of the hopper, silo or cyclone to store and transport the granules such as feed, and to close the inner space. It relates to an air knocker used to prevent the.

Particles are attached or rat hole phenomenon occurs on the inner wall surface of silo, hopper, cyclone (hereinafter referred to as 'powder tank') for storing and transporting granules such as feed. Problem occurs that the function is degraded. In order to prevent this, an air knocker, an impact generator using compressed air, is used.

The air knocker is generally fixedly installed on the outer wall of the powder tank, and the magnetic piston strikes the under piston by the force of the temporary release of compressed air, and continuously impacts the outer wall of the powder tank to store, discharge, and transport the powder. It is an automatic device that solves and prevents problems such as wall attachment, bridge, and rat hole phenomenon.

Looking at the configuration of the conventional air knocker, a magnetic piston is built into the interior of the cylinder, the cylinder head is coupled to the upper portion of the cylinder, the fixing plate is disposed in close contact with the magnetic piston in the upper portion of the cylinder, An under piston is disposed at a lower end in the interior, and the magnetic piston is interposed in the compression spring to receive a restoring force.

The magnetic piston is normally fixed to the fixed plate by magnetic force, and when high-pressure compressed air is injected into the cylinder through the air inlet of the cylinder head, the pressure inside the cylinder gradually rises to exceed the magnetic force of the magnetic piston. do. Then, the magnetic piston is pushed away sharply from the fixed plate, the pushed magnetic piston hits the under piston and thus transmits vibration to the wall surface of the powder tank, thereby preventing the powder from adhering to the inner surface of the powder tank. .

Then, when the air in the cylinder is exhausted again, the pressure inside the cylinder is lowered, and the magnetic piston is returned to its original state by the elastic force of the compression spring and fixed to the fixing plate.

In the conventional air knocker operated as described above, the elastic force of the compression spring is gradually weakened by the strong explosive force by the compressed air, and the return force of the magnetic piston is weakened, so that it may not be in close contact with the fixed plate. Accordingly, there was a problem that can not perform the function of the air knocker.

Due to this problem, in order to ensure the durability of the compression spring, the compression spring, which has been subjected to tens of thousands of durability tests on the compression spring, is applied to the air knocker.

On the other hand, in the conventional air knocker, since the pressure generated by the compressed air injected into the cylinder must be stronger than the counter force combined with the elastic force of the compression spring and the adhesion force by the magnetic force of the magnetic piston and the fixed plate, (It corresponds to the elastic force of the compression spring.) There was also a problem of energy loss.

On the other hand, the conventional air knocker, when considering the impact pressure of the magnetic piston due to the elastic force of the compression spring at the beginning of use, the instantaneous explosive force can be seen as a slight influence of the elastic force of the compression spring, There is also a problem in that the impact pressure is weakened as much.

Accordingly, the present invention is to solve the above problems, the object of the compression spring by removing the pressure spring that gives the return force to the magnetic piston, and replacing the removed pressure spring with a magnetic piston return device installed outside the cylinder, It is to provide an air knocker that can be used for a long time without using.

In addition, since the compression spring does not need to be used, the pressure generated by the compressed air injected into the cylinder needs only to be larger than the adhesion force by the magnetic force of the magnetic piston and the fixed plate, thereby improving energy efficiency. To provide an air knocker.

In addition, the blow pressure of the magnetic piston is to provide a uniform air knocker always under the selected pressure even in long-term use.

The present invention for achieving the above object is a cylinder with a built-in magnetic piston, a cylinder head coupled to the upper portion of the cylinder having an air inlet for introducing and blocking compressed air by the control of the solenoid valve, the upper side in the interior of the cylinder In the air knocker is provided with a fixed plate that is in close contact with the magnetic piston, the lower piston in the interior of the cylinder,

The magnetic piston return device is connected to the outside of the cylinder, the magnetic piston return device is the original operation after the magnetic piston hits the under piston by the compressed air injected through the air inlet of the cylinder head, By returning to the state to be in close contact with the fixed plate, the supply of compressed air on the cylinder side is stopped and connected to the outside of the cylinder to receive compressed air through another supply line and to provide the inside of the cylinder. It is characterized by.

In addition, an air injection hole into which compressed air is injected from the magnetic piston return device is formed at a lower end of the cylinder, and a first exhaust hole through which air is discharged while the magnetic piston hits the under piston is formed.

The magnetic piston return device,

A return device body in which the air inlet hole, the first connecting hole, the second connecting hole, and the second exhaust hole communicate with the internal space, respectively; An opening and closing actuator which is elastically coupled by the compression spring 28 in the inner space of the return device body and is capable of linear reciprocating motion; An air inlet coupled to the air inlet of the return device body; A connection hose connected to the air injection hole of the cylinder from the first connection hole of the return device body; And a connection exhaust pipe connected to the second connection hole of the return device body at the first exhaust hole of the cylinder.

According to the present invention constituted as described above, by eliminating the pressure spring for providing a return force to the magnetic piston, and replacing the removed pressure spring with a magnetic piston return device attached to the outside of the cylinder, it is not necessary to use a compression spring Long-lasting air knockers can be provided.

In addition, since it is not necessary to use a compression spring, the pressure generated by the compressed air injected into the cylinder need only be larger than the adhesion force by the magnetic force of the magnetic piston and the fixed plate, thereby improving the energy efficiency.

In addition, the blow pressure of the magnetic piston can always provide a uniform air knocker even under long-term use under the selected pressure.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, only this embodiment to make the disclosure of the present invention complete and to those skilled in the art to fully understand the scope of the invention It is provided to inform you.

1 is a perspective view of an air knocker according to the present invention, Figure 2 is a partially cutaway perspective view of the magnetic piston return device configured in the present invention, Figure 3 is a cross-sectional view of the air knocker according to the present invention.

The present invention provides a cylinder head 13 having a magnetic piston 12 therein, a cylinder head 13 coupled to an upper portion of the cylinder 10 and having an air inlet 13a for introducing and blocking compressed air under control of a solenoid valve. ), An air knocker having an under piston 16 disposed at a lower end of the cylinder 11 at an upper side of the cylinder 11. In (10), the magnetic piston return device 20 is connected to the outside of the cylinder 11.

The magnetic piston return device 20 is the original after the magnetic piston 12 hits the under piston 16 by the compressed air injected through the air inlet (13a) of the cylinder head 13, By returning to the state of to serve to give a return force to be in close contact with the fixing plate (15).

The magnetic piston return device 20 stops the compressed air supply to the cylinder 11 side and at the same time receives compressed air through another supply line to provide the inside of the cylinder 11. It is connected from the outside.

The under piston 16 functions to transmit the impact force to the powder tank by the magnetic piston 12 descends and strikes.

As shown in FIG. 1, an air inlet 13a through which compressed air flows under the control of a solenoid valve (not shown) is communicated with the inside of the cylinder 11 in the cylinder head 13.

The air injection hole 11a and the first exhaust hole 11b communicate with the inside of the cylinder 11 at the lower end of the cylinder 11.

The air injection hole 11a in the cylinder 11 is a portion in which compressed air is injected from the magnetic piston return device 20, and the first exhaust hole 11b has a magnetic piston 12 with an under piston 16. In the process of hitting the air is discharged.

Unexplained reference numeral 14 shown in Figure 1 is a 'mounting plate', the fastening hole (14a) is formed along the circumference of the mounting plate (14). The mounting plate 14 is bolted to the base plate 17 as shown in FIG.

Referring to FIG. 2, the magnetic piston return device 20 includes a return device body 21, an air inlet 22, a connection exhaust pipe 23, a connection hose 26, an opening and closing actuator 27, and a compression spring 28. Components are combined.

The return device body 21 has a cylindrical body having a size of about 1/5 of the cylinder 11 and has an inner space, but includes an air inlet hole 21a, a first connection hole 21b, and a second connection hole 21c. And the second exhaust hole 24 communicate with the internal space, respectively.

The inner space of the return device body 21 is formed in a vertical line at the center of the body, and there is an air inlet hole 21a on the upper surface of the return device body 21, and a first connection to the upper side of the return device body 21. A ball 21b is formed, and a second connecting hole 21c is formed in the lower side of the return device body 21, and a lower side of the return device body 21 corresponding to the opposite side of the second connecting hole 21c. In the second exhaust hole 24 is located. In other words, the second connecting hole 21c and the second exhaust hole 24 are preferably positioned in a straight line horizontally, in order to enable a smooth exhaust action.

The opening and closing actuator 27 receives an elastic force by the compression spring 28 in the inner space of the return device body 21 and is coupled to the linear reciprocating motion.

An air inlet 22 for receiving compressed air through another supply line is connected to the air inlet hole 21a of the return device body 21.

The air inlet 22 is connected to the solenoid valve (not shown) on the cylinder 11 side, so that compressed air is introduced or blocked under control. That is, the magnetic piston return device 20 is operated by receiving compressed air through another supply line at the same time the supply of compressed air on the cylinder 11 side is stopped.

The connection hose 26 is connected to the air injection hole 11a of the cylinder 11 from the first connection hole 21b of the return device body 21.

The connecting exhaust pipe 23 is connected to the second connecting hole 21c of the return device body 21 at the first exhaust hole 11b of the cylinder 11.

The connection hose 26 is coupled to the connection hole 21b formed at the upper end of the return device body 21 at one end thereof, and the other end of the connection hose 26 is connected to the cylinder 11. It is connected to the air injection hole 11a.

In the state where the opening and closing actuator 27 is located in the upper space of the return device body 21 by the elastic force of the compression spring 28, the outer peripheral surface of the opening and closing actuator 27 is the upper part of the return device body 21. The first connecting hole 21b is blocked at the side surface.

On the other hand, when the opening and closing actuator 27 moves downward by the compressed air introduced through the air inlet hole 21a, the first connection hole 21b is opened so that the compressed air is provided through the first connection hole 21b. Compressed air flows into the air injection hole 11a of the cylinder 11 via the connection hose 26, and a return force is generated by the compressed air flowing in from the lower part of the cylinder 11 to generate the magnetic piston 12. Is in close contact with the fixed plate 15.

Here, the upper end of the opening and closing actuator 27 is located below the first connection hole 21b in a state where the opening and closing actuator 27 is lowered as much as it flows in through the air inlet hole 21a of the compressed air. The second connecting hole 21c and the second exhaust hole 24 are closed by the outer circumferential surface of the lowered opening / closing actuator 27.

The cylinder 11 and the cylinder head 13 are screwed, and the fixing plate 15 is coupled by a bolt coupled through the center of the cylinder head 13. The fixing plate 15 can be fixed by adjusting the position in the cylinder by adjusting the screw coupling of the bolt.

The mounting plate 14 has a central portion protruding to a certain height to form a screw portion on the outer circumference, and a female screw portion is formed on the inner surface of the lower end of the cylinder 11 to be screwed together. The magnetic piston 12 has a magnetic portion 12a embedded in an upper surface thereof.

4 to 6 are views for explaining the operation of the present invention, Figure 4 is a state in which compressed air is injected into the air knocker, Figure 5 is the compressed air injected into the air knocker is a vacuum state the powder tank 6 is a state in which the magnetic piston of the air knocker is returned to its original state, and FIG. 7 is an embodiment showing the installation state of the air knocker according to the present invention.

As shown in Figure 7, the present invention is fixed to the base plate 17 fixed to the outer wall of the powder tank 100 by using a mounting plate 14 bolts. The operation of the present invention configured as described above in the installed state will be described with reference to FIGS. 4 to 6.

In the initial state in which compressed air is not injected, the magnetic piston 12 is kept in close contact with and fixed to the fixed plate 15 by magnetic force.

In FIG. 4, the solid arrow indicates the flow of compressed air, and the dotted arrow shows the exhaust flow.

Referring to FIG. 4, when the compressed air is introduced through the air inlet 13a by the control of the solenoid valve, the pressure inside the cylinder 11 is increased, and when the magnetic force of the magnetic piston 12 exceeds, the momentary The magnetic piston 12 is lowered by the explosive force to strike the under piston 16, and the impact force vibrates the outer wall of the base plate 17 and the powder tank 100, so that the powder in the powder tank 100 It will not be attached to the wall.

As the magnetic piston 12 operates, the air that is below the magnetic piston 12 in the cylinder 11 flows into the exhaust connection pipe 23 through the first exhaust hole 11b, and thus, of the return device body 21. It is discharged to the outside through the second exhaust hole 24 of the return device body 11 through the inner space.

Here, the compressed air supplied into the cylinder 11 is not made continuously, the supply and stop occurs instantaneously alternately with a time difference, the supply of compressed air on the cylinder 11 side and at the same time through the other supply line Compressed air is supplied to the magnetic piston return device 20 side.

Thereafter, the magnetic piston return device 20 is acted.

Referring to FIG. 5, the compressed air flows into the magnetic piston return device 20 through the air inlet 22 of the return device body 21, and the opening and closing actuator 27 descends by the compressed air. Accordingly, compressed air is injected through the air injection hole 11a in the lower portion of the cylinder 11 through the connection hose 26 through the connector 25 connected to the first connection hole 21b. As a result, the internal pressure of the lower portion of the magnetic piston 12 is increased by the pressure of the compressed air, so that the magnetic piston 12 moves toward the fixing plate and is tightly fixed by magnetic force.

Here, since the second exhaust hole 24 provided in the returning device body 21 is closed by the opening and closing actuator 27 in the lowered state, the second exhaust hole 24 is closed through the first exhaust hole 11b of the cylinder 11. Since compressed air is not discharged, it does not affect the provision of a return force to the magnetic piston 12.

Referring to FIG. 6, when the supply of compressed air to the magnetic piston return device 20 is stopped, the opening and closing actuator 27 is moved upward by the elastic force of the compression spring 28. Then, the first connection hole 21b is closed by the raised opening / closing actuator 27.

On the other hand, in the state in which the opening and closing actuator 27 is finished, the lower end portion of the opening and closing actuator 27 is positioned above the second connecting hole 21c and the second exhaust hole 24 and the second connecting hole 21c. ) And the second exhaust hole 24 are open and communicate with each other.

In this way, by repeatedly injecting or stopping the high-pressure compressed air alternately to the cylinder 11 side and the magnetic piston return device 20 side to generate a repetitive vibration on the outer wall of the powder tank 100. By repeating this process, it is easy to move the powder or powder that is supplied and injected into the powder tank 100.

Although the present invention has been described with reference to the drawings exemplified as above, the present invention is not limited to the embodiments and drawings disclosed herein, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. Of course it can be done.

1 is a perspective view of an air knocker according to the present invention.

Figure 2 is a partially cutaway perspective view of the magnetic piston return device configured in the present invention.

3 is a cross-sectional view of an air knocker according to the present invention.

4 to 6 are views for explaining the operation of the present invention,

4 is a state in which compressed air is injected into the air knocker.

5 is a state in which the compressed air injected into the air knocker is in a vacuum state and the hammer strikes the outer wall of the powder tank.

6 is a state in which the magnetic piston of the air knocker is returned to its original state.

7 is an embodiment showing an installation state of the air knocker according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: air knocker 11: cylinder

11a: air injection hole 11b: first exhaust hole

12: magnetic piston 12a: magnetic

13 cylinder head 13a air inlet

14: mounting plate 14a: fastening hole

15: fixed plate 16: under piston

17: base plate

20: magnetic piston return device 21: return device body

22: air inlet 23: exhaust connector

24: second exhaust hole 25: connector

26: connecting hose 27: opening and closing actuator

28: compression spring 100: powder tank

Claims (2)

A cylinder head 13 having a magnetic piston 12 embedded therein, a cylinder head 13 coupled to an upper portion of the cylinder 10 and having an air inlet 13a for introducing and blocking compressed air under the control of a solenoid valve. An air knocker 10 having an under piston 16 disposed at a lower end of the cylinder 11 is disposed at an upper side of the cylinder 11. To Magnetic piston return device 20 is connected to the outside of the cylinder 11, The magnetic piston return device 20 is the original after the magnetic piston 12 hits the under piston 16 by the compressed air injected through the air inlet (13a) of the cylinder head 13, By returning to the state of being in close contact with the fixed plate 15, the supply of compressed air on the cylinder 11 side is stopped and at the same time the compressed air is supplied through another supply line to the interior of the cylinder (11) Air knocker, characterized in that connected to the outside of the cylinder (11) to provide. The method of claim 1, At the lower end of the cylinder 11, air is injected into the air injection hole 11a through which the compressed air is injected from the magnetic piston return device 20, and the magnetic piston 12 hits the under piston 16. The first exhaust hole 11b discharged is formed, The magnetic piston return device 20, A return device body 21 in which the air inlet hole 21a, the first connecting hole 21b, the second connecting hole 21c and the second exhaust hole 24 communicate with the internal space, respectively; An opening / closing actuator 27 which is elastically coupled by the compression spring 28 in the inner space of the return device body 21 and is capable of linear reciprocating movement; An air inlet 22 coupled to the air inlet hole 21a of the return device body 21; A connection hose (26) connected to the air injection hole (11a) of the cylinder (11) in the first connection hole (21b) of the return device body (21); And a connection exhaust pipe (23) connected to the second connection hole (21c) of the return device body (21) in the first exhaust hole (11b) of the cylinder (11).

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