KR102165083B1 - Deburring Device for Copper Bus Bar - Google Patents

Abstract

The present invention relates to a deburring apparatus for processing copper bus bar and, particularly, to a deburring apparatus for processing copper bus bar, which deburrs the periphery of a screw hole formed on a copper bus bar component by dropping a deburring tool, and simultaneously blows out generated debris with air pressure to maximize work convenience. The deburring apparatus comprises: a nozzle (5000) receiving air from an external sir supply device to transfer the air to a part seating unit; a fixating bracket (7000) installed at one end of a supporting housing in order to fixate the nozzle; a fixating bolt (8000) for fixating the fixating bracket at the supporting housing; and a long hole (9000) formed on the fixating bracket in order to adjust the position of a bolt.

Description

Deburring Device for Copper Bus Bar}

The present invention relates to a deburring device for processing the Dongbu subbar, and in particular, to maximize the convenience of work by lowering the deburring tool to deburr the burr around the screw hole formed in the Dongbu subbar and simultaneously blowing out the generated debris with air pressure. It relates to a deburring device for processing the eastern subbar, characterized in that the configuration.

In general, a bus bar made of a thick plate such as copper or aluminum is used in switchboards, distribution boards, control panels, etc. to connect the terminals to the terminals.The busbars are mounted and different according to the design of the switchboard, etc. In order to connect to the member, processing such as cutting or bending or punching of a plurality of fastening holes is required.

Therefore, a busbar processing device, which is a press device, is used for the processing of the busbar as described above.

The conventional busbar processing apparatus as described above is generally composed of a main body having a driving device built therein, and a bending machine, a cutter, a punching machine, etc. mounted on the upper part of the main body. The bending machine, cutter, and punching machine are constructed by mounting processing means suitable for each purpose to a plurality of presses installed on the upper part of the main body, and are operated by a driving device such as a hydraulic pump installed inside the main body. In addition, the busbar processing apparatus is further equipped with a terminal crimping machine for forming an electric wire terminal composed of metal pieces by crimping the end of the electric wire. The terminal crimping machine is made by attaching a terminal processing tool to the press, In general, it is not constituted by a separate press, and if necessary, the tool of the bending machine is generally used by replacing the tool for terminal processing.

The busbar, which has been processed and formed such as bending, cutting, punching, etc. through the busbar processing apparatus as described above, is mounted on a switchboard, and the busbar is processed and molded in various forms according to the design of the switchboard, etc. In some cases, it is necessary to immediately process and form the busbar while installing the switchboard.

However, in general, the places where switchboards, distribution boards, and control panels are installed are often narrow, whereas in the conventional busbar processing apparatus as described above, a driving device such as a hydraulic pump is provided inside and a plurality of presses are formed at the top. Therefore, since the device is heavy and large and it is impossible to move the device, there is a problem that it is difficult to immediately process and mold at an installation place such as a switchboard.

In view of this, in Korean Patent Registration No. 10-0554339 and Korean Utility Model Registration No. 20-0402851, processing is performed by connecting a hydraulic pump separately provided with a device in order to solve the above problems, The upper and lower tools that perform processing and molding such as bending, cutting, punching, and terminal crimping are configured to be replaced and used as necessary in the upper and lower tool holders installed in the processing equipment. It provides a portable busbar processing device that reduces the size and performs various processing operations with a single press device.

However, in the conventional portable busbar processing apparatus, the processing operation is independently performed once, so in order to process the busbar that is bent more than two times, the processing operation must be repeated several times, and one busbar processing operation at a time. Because only possible, there is a problem that the work is cumbersome and time-consuming.

For this reason, in Korean Patent Registration No. 10-668709, the upper and lower bending tools that perform bending are configured to enable simultaneous processing on a plurality of busbars of different widths and shapes to improve the accuracy and efficiency of work. I am trying to raise it.

On the other hand, burrs are generated around the screw holes in the process of processing the Dongbu bar, and a deburring device is used to remove them.As the debris generated during the deburring process is removed with a brush, it is difficult to completely remove the burrs and the operator There was a high concern that a safety accident would occur.

In other words, the deburring operation can be performed after removing debris generated during the deburring process.Because the deburring operation is a simple operation of removing the burr by raising and lowering the deburring tool, the deburring tool presses the finger with carelessness. There are cases where safety accidents occur, and accordingly, workers are injured.

An object of the present invention is to solve the above-described problem, and to deburr the periphery of the screw hole of the eastern subbar and at the same time to properly remove debris left in the working area with air pressure.

As a means to achieve the above object,

The present invention is a deburring tool (1100) for deburring the periphery of the screw hole of the Dongbu sub-bar part, a part seating part 1200 for seating the part to be deburred, and a supporting housing (1300) for supporting the part receiving part from the bottom In the Dongbu sub-bar deburring device comprising a nozzle (5000) for receiving air from an external air supply device and transmitting it to the part seating unit; A fixing bracket 7000 installed at one end of the support housing to fix the nozzle; A fixing bolt (8000) for fixing the fixing bracket to the support housing; It is characterized in that it comprises a long hole 9000 formed in the fixing bracket to adjust the position of the bolt.

In addition, an air storage container 1000 installed at one end of the Dongbu sub-bar deburring device and storing air for supplying to the part seating unit; An air supply means (2000) connected to the air storage container to receive and temporarily store air contained in the air storage container; A control valve (4000) installed at one side of the output end of the air supply means to regulate air discharged to the nozzle; It is characterized in that it further comprises a footrest switch 6000 connected to one side of the air supply means to induce air supply by outputting an air supply switching signal.

In addition, it is made between the air storage container and the air supply means further comprises an air outlet valve 100 for preventing reverse flow of air; The air outlet valve includes: the air output unit 10 formed by forming a first air flow pipe 11 through which air passes through one side and a first coupling pipe 12 formed at the other side; A circular ring 21 formed to be inserted into the first coupling pipe and having a diameter smaller than the inner diameter of the first coupling pipe, a protrusion 22 formed inside the circular ring, and formed between the protrusions. Air passing means (20) made of an air flow hole (23) and; A second coupling pipe 42 coupled to the inside of the first coupling pipe 12 of the air output unit 10 is formed on one side, and a second air flow pipe 41 through which air passes is formed on the other side. An air input unit 40 formed; It is coupled to the inside of the second air flow pipe 41 and is temporarily coupled to the bypass disk 20 to induce air to flow through the first air flow pipe 11 of the air output unit 10, or A temporary blocking ball 30 temporarily coupled to the inlet of the second air flow pipe 42 of the input unit 40 to block the penetration of contaminants through the second air flow pipe 42; A plurality of pieces are installed inside the second coupling pipe at regular intervals, and comprises a blocking ball guide means 50 for guiding the temporary blocking ball to move left and right without deviating from the horizontal center of the second coupling pipe. This is a feature.

In addition, a contaminated air burner unit 200 for burning contaminated air is further installed at one end of the Dongbu Subbar deburring device, wherein the contaminated air burner unit includes: a switching means 221 for supplying arc discharge electricity; Arc discharge re-ignition switching means 222 mounted on the switching means 221 for supplying arc discharge electricity to automatically re-ignite the arc discharge; The arc discharge re-ignition circuit unit 223 is connected to the arc discharge re-ignition switching means 222 and outputs a signal for re-ignitioning the arc discharge.

In addition, the arc discharge re-ignition switch means 222 is installed on the edge of the arc discharge electricity supply switching means 221 and rotates simultaneously when the arc discharge electricity supply switching means 221 rotates ( 222a); A first sliding transfer member (222b) formed by forming a rack gear (222e) on a contact surface with the pinion gear (222a) and having a cylindrical or square column shape so as to slide horizontally by rotation of the pinion gear (222a); A second sliding transfer member (222c) coupled to the inner side of the first sliding transfer member (222b) and moving in conjunction with the first sliding transfer member (222b) when it moves to switch the arc discharge re-ignition circuit unit (223); A tension spring (222d) connected to the end of the first sliding transfer member (222b) and the start of the second sliding transfer member (222b) and serving to maintain the switching state of the arc discharge re-ignition circuit unit (223). It is characterized by including.

In addition, the arc discharge re-ignition circuit unit 223 includes a DC power supply unit 101 installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries, or general batteries in series; An arc discharge re-ignition switch 102 which has one end connected to the DC power supply and is switched on when the arc discharge re-ignition switching unit is rotated; An oscillation booster circuit part 103 for outputting a boosted AC current by supplying electricity when the arc discharge re-ignition switch is turned on; A switching unit 108 for supplying electricity to a discharge electrode connected to the output terminal of the oscillation booster circuit unit and turned on by electric supply; A high-voltage boosting circuit part 107 installed at an output terminal of the switching part for supplying electricity to the discharge electrode and generating a high voltage; A high-pressure discharge spacer (113a, 113b) formed by connecting a high-voltage power supplied by the high-voltage boosting circuit unit; A discharge electrode 114 for inducing a flame to burn by igniting the discharge while being discharged using the power provided by the high-pressure discharge spacer; The discharge electrode and the base end are connected, and the emitter end and the collector end are connected to the oscillation transformer and the switching unit for ignition of the discharge electrode, and when a spark is generated in the space, it is switched while forming a closed circuit by hot electrons to switch the discharge electrode electricity When the arc discharge flame is turned off by external wind or moisture, the closed circuit is broken due to the extinction of hot electrons and the switching is turned off. Accordingly, the power to the switching unit for supplying electricity to the discharge electrode is turned off. It is characterized by including a switching unit 118 for blocking the discharge electrode that functions to induce the discharge electrode to be ignited by turning it on.

As described above, the present invention has the effect of deburring the periphery of the screw holes of the parts constituting the eastern subbar and at the same time removing debris left in the working area with air pressure appropriately.

Figure 1 is a photograph showing the configuration of the present invention.
Figure 2 is a photograph of another angle showing the configuration of the present invention.
3 is a conceptual diagram of a deburring operation using the present invention.
Figure 4 is an embodiment of the installation of the air pressure providing means of the present invention.
Figure 5 is a block diagram of the valve of the present invention.
6a, b, and c are conceptual diagrams for blocking contaminants using the present invention.
7a, b, c are conceptual diagrams in which air is discharged using the present invention.
Figure 8 is a block diagram of an arc discharge configuration for removing polluted air of the present invention.
9 is a first operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention.
10 is a second operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention.
11 is a third operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

In addition, a preferred embodiment of the present invention to be implemented below is already provided in each system function configuration in order to efficiently describe the technical components constituting the present invention, or system functions commonly provided in the technical field to which the present invention belongs. The configuration will be omitted as much as possible, and a functional configuration that should be additionally provided for the present invention will be mainly described.

If one of ordinary skill in the art to which the present invention pertains, among the functional configurations not shown below and omitted, the functions of the components already used in the past will be easily understood, and the configurations omitted as described above. The relationship between the elements and the elements added for the present invention will also be clearly understood.

In addition, in the following embodiments, terms will be appropriately modified and used so that those of ordinary skill in the art can clearly understand the key technical features of the present invention in order to efficiently describe the core technical features of the present invention. It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are one means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. It is only.

In addition, it is to be understood that all detailed descriptions listing specific embodiments as well as principles, aspects and embodiments of the present invention are intended to include structural and functional equivalents of these matters. It should also be understood that these equivalents include not only currently known equivalents, but also equivalents to be developed in the future, that is, all devices invented to perform the same function regardless of structure.

Thus, for example, the block diagrams herein are to be understood as representing a conceptual perspective of exemplary circuits embodying the principles of the invention. Similarly, all flowcharts, state transition diagrams, pseudocodes, etc. are understood to represent various processes performed by a computer or processor, whether or not the computer or processor is clearly depicted and that can be represented substantially in a computer-readable medium. Should be.

The functions of the various elements shown in the figures, including a processor or functional block represented by a similar concept, may be provided by the use of dedicated hardware as well as hardware having the ability to execute software in association with appropriate software. When provided by a processor, the function may be provided by a single dedicated processor, a single shared processor, or a plurality of individual processors, some of which may be shared.

In addition, the explicit use of terms presented as processor, control, or similar concepts should not be interpreted exclusively by referring to hardware capable of executing software, and without limitation, digital signal processor (DSP) hardware, ROM for storing software. It should be understood to implicitly include (ROM), RAM, and non-volatile memory. Other commonly used hardware may also be included.

In the claims of this specification, components expressed as means for performing the functions described in the detailed description include all types of software including, for example, a combination of circuit elements or firmware/microcode that perform the above functions. It is intended to include all methods of performing a function to perform the function, and is combined with suitable circuitry for executing the software to perform the function. Since the invention defined by these claims is combined with the functions provided by the various enumerated means and combined with the manner required by the claims, any means capable of providing the above functions are equivalent to those conceived from this specification. It should be understood as.

The above-described objects, features, and advantages will become more apparent through the following detailed description in connection with the accompanying drawings, whereby those of ordinary skill in the technical field to which the present invention pertains can easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Before describing various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of configurations and arrangements of elements described in the following detailed description or illustrated in the drawings. The present invention may be implemented and practiced in different embodiments and may be performed in various ways. Also, the device or element orientation (eg "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral"), etc. are used only to simplify the description of the present invention, and related devices Or you may find that the element simply indicates or does not mean that it should have a specific orientation.

Figure 1 is a photograph showing the configuration of the present invention.

Figure 2 is a photograph of another angle showing the configuration of the present invention.

3 is a conceptual diagram of a deburring operation using the present invention.

Figure 4 is an embodiment of the installation of the air pressure providing means of the present invention.

Figure 5 is a block diagram of the valve of the present invention.

6a, b, and c are conceptual diagrams for blocking contaminants using the present invention.

7a, b, c are conceptual diagrams in which air is discharged using the present invention.

Figure 8 is a block diagram of an arc discharge configuration for removing polluted air of the present invention.

9 is a first operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention.

10 is a second operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention.

11 is a third operation diagram of a switching means for supplying arc discharge electricity of the arc discharge circuit of the present invention,

The deburring apparatus of the present invention basically includes a deburring tool 1100 for deburring around a screw hole of a Dongbu sub-bar component as shown in Figs. 1 and 2, and a part seating part 1200 for seating the Dongbu sub-part to be deburred. And, it consists of a housing for support (1300) that supports the part seating portion from the bottom.

In addition, air is injected into the part seating part to automatically remove the deburred debris from the part seating part 1300.

In addition, a nozzle 5000 for receiving air from the air supply means and injecting air to the part seating part is further installed, and a fixing bracket 7000 installed at one end of the support housing to fix the nozzle; A fixing bolt (8000) for fixing the fixing bracket to the support housing; To adjust the position of the bolt constitutes a long hole (9000) formed in the bracket for fixing.

In addition, in the present invention, the air storage container and the air supply means can be installed at one end of the deburring device, and the air storage container and the air supply means are installed at one end of the housing of the deburring device, and the nozzle is removed by pumping the air supply means. Air is output through and air is supplied to the processed material. That is, the air stored in the air storage container 1000 is first transferred to the air supply means 2000 and discharged to the nozzle 5000 through the output end of the air supply means, so that air can be injected into the part seating part.

In the present invention, when the foot switch 6000 is pressed to inject air into the part seating part after the deburring operation, the driving device for pumping air is driven, the air that has flowed into the air supply means 2000 is pressurized and the nozzle 5000 ) To discharge.

At this time, a control valve 4000 is provided between the air supply means 2000 and the nozzle 5000 to control the amount of air discharged to the nozzle 5000.

Preferably, the nozzle 5000 employs a valve at its end to be opened momentarily only when the discharge pressure of air is greater than or equal to a predetermined value, so that the air can be intermittently interrupted.

On the other hand, the air pressure output valve 100 serves to prevent external contaminants from penetrating into the air pressure providing device, and to discharge the air from the air pressure providing device to the outside of the air pressure providing device. And, it consists of an air passing means 20, a temporary blocking ball 30, an air input unit 40, and a blocking ball guide means 50.

The air output unit 10 includes a first air pressure flow pipe 11 through which air passes, and a first coupling pipe 12 at the other side.

The air passing means 20 is inserted into the first coupling pipe of the air pressure flow valve, and has a circular ring 21 having a diameter smaller than the inner diameter of the first coupling pipe, and formed inside the circular ring. It consists of a protrusion 22 and a hole 23 for air pressure flow formed between the protrusions.

The air input unit 40 is a second air flow pipe through which a second coupling pipe 42 coupled to the inner side of the first coupling pipe 12 of the air output unit 10 is formed on one side and air passes through the other side. (41) is formed and made.

The temporary blocking ball 30 is coupled to the inside of the second air flow pipe 41 and is temporarily coupled to the bypass disk 20 so that air is passed through the first air flow pipe 11 of the air output unit 10. Induces the flow to flow or is temporarily coupled to the inlet of the second air flow pipe 42 of the air input unit 40 to block the penetration of contaminants through the second air flow pipe 42.

The blocking ball guide means 50 is installed inside the second coupling pipe at regular intervals, and serves to guide the temporary blocking ball to move left and right without deviating from the horizontal center of the second coupling pipe.

The operation of the present invention made as described above is as follows.

First, looking at the process of controlling the flow of air, external contaminants are introduced through the first air flow pipe 11 of the air output unit 10 as shown in FIGS. 4A, 4B, and 4C.

Thereafter, the second temporary blocking ball 30 is pushed out, and at this time, the second temporary blocking ball 30 moves along the blocking ball guide means 50.

Thereafter, the second temporary blocking ball 30 is further pushed to close the inlet of the second air flow pipe 42 of the air input unit 40.

Then, the contaminants penetrating through the air output unit 10 cannot pass through the air input unit 40 and are intercepted.

Second, looking at the process of generating the air flow, it is drawn in through the second air flow pipe 42 of the air input unit 40 as shown in FIGS. 5A, 5B, and 5C.

Thereafter, the second temporary blocking ball 30 is pushed out, and at this time, the second temporary blocking ball 30 moves along the blocking ball guide means 50.

Thereafter, the second temporary blocking ball 30 is further pushed to come into close contact with the inlet of the air passage means 20 coupled to the air output unit 10.

Then, the air flowing through the air input unit 40 flows through the second temporary blocking ball 30 and the air flow hole 22 of the air pressure passing means 20.

In addition, the number of blocking ball guide means 50 is preferably about 3 to 5, and at least 3 is preferably installed.

In addition, the reason for limiting the number of blocking ball guide means 50 to 5 or less is that the temporary blocking ball 30 may move more naturally as the number of blocking ball guide means 50 increases, but the flow of air is reduced. This is because the air should flow between the blocking ball guide means 50 when generating the bar, because if a large number of blocking ball guide means 50 exist, the flow of air is blocked by that much.

In the present invention, a contaminated air burner is additionally installed at one end of a deburring device to ignite contaminated air by spark discharge, thereby configuring a device to burn off contaminants.

Arc discharge re-ignition switching means 222 is further mounted to the switching means 221 for supplying arc discharge electricity of the contaminated air burner unit 200, and the arc discharge re-ignition switching means 222 has arc discharge re-ignition. The arc discharge re-ignition circuit unit 223 is installed to be contacted, and the end of the arc discharge re-ignition circuit unit 223 is connected to an electrical output terminal.

That is, in the present invention, when the switching means 221 for supplying arc discharge electricity is operated, the arc discharge re-ignition switching means 222 is operated at the same time, and accordingly, the initial arc discharge is ignited, and then the arc discharge is caused by external wind or When turned off due to moisture, the arc discharge re-ignition circuit unit 223 linked to the arc discharge re-ignition switching means 222 operates to re-ignite the arc discharge to prevent the arc discharge from being turned off.

That is, when the switching means 221 for supplying arc discharge electricity is rotated, the arc discharge re-ignition switching means 222 simultaneously rotates to turn on the arc discharge re-ignition circuit unit 223, and accordingly, the arc discharge re-ignition circuit unit ( As the discharge electrode connected to the output terminal of 223) is ignited, electricity is ignited. When ignited by the discharge electrode, the power supplied to the discharge electrode is turned off, so that no more discharge occurs.

And, at this time, since the arc discharge re-ignition switching means 222 maintains the switching state, the arc discharge re-ignition circuit unit 223 continues to operate, and accordingly, the arc discharge sparks due to external wind or moisture. When this is turned off, the arc discharge re-ignition circuit unit 223 automatically operates to ignite the discharge electrode again to ignite the arc discharge, so that the spark caused by the arc discharge is continuously maintained.

In the drawings, reference numeral 201 denotes an arc power supply unit, 210 denotes a power supply control unit, and 220 denotes an arc power supply line. At this time, when the switching means 221 for supplying arc discharge electricity is rotated, electricity for arc discharge is supplied to generate arc discharge sparks.

In the present invention, the arc discharge re-ignition switching means 222 is coupled to the arc discharge electricity supply switching means 221 so that the arc discharge re-ignition switching means 222 is operated while the arc discharge electricity supply switching means 221 is operated. The main feature is that the arc discharge re-ignition circuit unit 223 is switched while operating.

That is, in the present invention, when the switching means 221 for supplying arc discharge electricity is operated, the arc discharge re-ignition switching means is operated by mechanically touching the arc discharge re-ignition circuit unit 223 to operate.

The arc discharge re-ignition switching means 222 of the present invention includes a pinion gear 222a, a first sliding transfer member 222b, a second sliding transfer member 222c, and a tension spring 222d.

The pinion gear 222a is installed on the edge of the switching means 221 for supplying arc discharge electricity and rotates simultaneously when the switching means 221 for supplying arc discharge electricity rotates.

The first sliding transfer member 222b has a cylindrical or square column shape so as to slide horizontally by rotation of the pinion gear 222a, and a rack gear 222e is formed on a contact surface with the pinion gear 222a.

The second sliding transfer member 222c is coupled to the inner side of the first sliding transfer member 222b, and when the first sliding transfer member 222b moves, it moves in conjunction with it to switch the arc discharge re-ignition circuit unit 223.

The tension spring 222d is connected to the end of the first sliding transfer member 222b and the start of the second sliding transfer member 222b, respectively, and serves to maintain the switching state of the arc discharge re-ignition circuit unit 223. .

In the following, an operation of the arc discharge re-ignition switching means 222 will be described.

When the switching means 221 for supplying arc discharge electricity is rotated to ignite the arc discharge, the pinion gear 222a formed on the edge of the switching means 221 for supplying arc discharge electricity is rotated.

When the pinion gear 222a rotates, the rack gear 222e of the first sliding transfer member 222b moves, and the first sliding transfer member 222b moves to the right.

Then, the second sliding transfer member 222c is coupled to the inner side of the first sliding transfer member 222b to move the arc discharge re-ignition circuit unit 223 to be switched.

Thereafter, when the switching means for supplying arc discharge electricity is continuously rotated to increase the amount of electricity supplied to increase the arc discharge spark, the first sliding transfer member 222b continues to move to the right, and at this time, the second sliding transfer member 222c Since is in a state of being touched on the arc discharge re-ignition circuit, the tension spring is stretched so that the second sliding transfer member 222c does not move any more.

That is, even if the pinion gear is continuously rotated by continuously rotating the switching means 221 for supplying arc discharge electricity, the second sliding transfer member 222c does not move and only keeps the switching state of the arc discharge re-ignition circuit unit 223 It is to let.

In addition, when the switching means for arc discharge electricity supply 221 is rotated in the opposite direction to reduce the arc discharge flame, the first sliding transfer member 222b moves to the left, and at this time, the tension spring 222d operates, so the second sliding The transfer member 222c does not move and keeps the switching state of the arc discharge re-ignition circuit unit 223.

Thereafter, when the switching means 221 for supplying the arc discharge electricity is completely turned, the second sliding transfer member 222c moves along the first sliding transfer member 222b to turn off the switching of the arc discharge re-ignition circuit unit 223. Will be ordered.

Hereinafter, a detailed configuration of the arc discharge re-ignition circuit unit 223 applied to the present invention will be described.

The arc discharge re-ignition circuit unit of the present invention includes a DC power supply unit 101, an arc discharge re-ignition switch 102, an oscillation booster circuit part 103, a switching part 108 for supplying electricity to a discharge electrode, and a high voltage booster circuit part ( 107), high-pressure discharge spacers 113a and 113b, a discharge electrode 114, and a switching unit 118 for discharging electrode off.

The DC power supply unit 101 is installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries or general batteries in series.

The arc discharge re-ignition switch 102 has one end connected to the DC power supply, and is switched on when the arc discharge re-ignition switching means is rotated.

The oscillation boosting circuit unit 103 is supplied with electricity when the arc discharge re-ignition switch is turned on to output a boosted AC current.

The switching unit 108 for supplying electricity to the discharge electrode is connected to the output terminal of the oscillation booster circuit unit and is turned on by electric supply.

The high voltage booster circuit part 107 is installed at the output terminal of the switching part for supplying electricity to the discharge electrode and generates a high voltage.

The high-pressure discharge spacers 113a and 113b are formed by connecting a high-voltage power supplied by a high-pressure boosting circuit.

The discharge electrode 114 is ignited while being discharged using a power provided by a high-pressure discharge spacer to induce a spark to be generated.

The discharge electrode blocking switching unit 118 is connected to the discharge electrode and the base end, and the emitter end and the collector end are connected to the oscillation transformer and the switching unit for supplying electricity to the discharge electrode. Switching while forming a closed circuit cuts off the power to the discharge electrode electricity supply switching unit to block the discharge electrode from being ignited.When the arc discharge flame is turned off by external wind or moisture, the closed circuit is broken due to the extinction of hot electrons and the switching is turned off. Accordingly, it serves to induce the discharge electrode to be ignited by turning on the power to the switching unit for supplying electricity to the discharge electrode.

Hereinafter, the operation of the arc discharge re-ignition circuit unit will be described.

First, when the arc discharge re-ignition switch 102 is turned on, the DC power supply 101 is connected to supply power to the oscillation booster circuit part 103, and a high voltage is applied to the secondary side of the oscillation booster circuit part 103.

The power induced in the secondary side becomes a half-wave DC power through the rectifier diode 106, and this half-wave DC power becomes a more stable DC power source due to the charging/discharging action of the capacitor 121.

This DC power is applied to the anode end of the thyristor (discharge electrode switching unit 108) through the primary coil of the high voltage booster circuit unit 107, while this DC power is charged to the capacitor 110 through a resistor. . The increased voltage passes through the diak 111 and triggers the discharge electrode switching unit 108 so that the anode end and the cathode end are switched so that the operation of the high voltage oi transformer booster circuit unit 107 is performed, and accordingly, the high voltage boost A high voltage voltage is induced in the secondary coil of the circuit unit 107, and the induced high voltage causes a secondary discharge between the discharge spacers 113a and 113b and spark discharge between the discharge electrodes 114.

This spark discharge causes an ignition function in the space located between the discharge electrodes 114. When the space is ignited in this way, an induced voltage is generated by hot electrons at both ends of the discharge electrode by the spark.

The induced voltage induces a closed circuit at the emitter end and the collector end of the discharge electrode blocking switching unit 118 while activating the base end of the discharge electrode blocking switching unit 118 to turn off the power to the switching unit for supplying electricity to the discharge electrode. Will be ordered.

That is, the voltage between the resistor 119 and the capacitor 110 flows through the diode 120 between the emitter terminal and the collector terminal of the switching unit 118 for discharging electrode off and is bypassed. ) And the capacitor 110 decreases, and when the voltage between the resistor 109 and the capacitor 110 decreases, the trigger signal directed to the switching unit 108 for supplying electricity to the discharge electrode is stopped. As the stage and the casing stage are turned off, current does not flow through the primary coil and the secondary coil of the high-voltage booster circuit unit 107 to stop the spark discharge between the discharge electrodes.

If the arc discharge action is stopped due to the influence of external wind, etc., the flow of current before flowing by hot electrons at both ends of the discharge electrode 114 disappears, and by doing so, the emitter end and the base of the switching unit 118 for blocking the discharge electrode The bias voltage flowing between the stages disappears and the switching unit 118 for blocking the discharge electrode is turned off.

As the switching unit 118 for blocking the discharge electrode is turned off, the bypass voltage between the resistor 109 and the capacitor 110 through the diode 120 disappears, and this voltage is charged in the capacitor 110.

This charged voltage leads to a breakover phenomenon of the diak 111, and the diac sends a trigger signal to the switching unit 108 for supplying electricity to the discharge electrode to start arc discharge again.

1000: air storage container
2000: Air supply means
4000: air control valve
5000: nozzle
6000: foot switch
7000: bracket
8000: fixing bolt

Claims (6)

Including a deburring tool (1100) for deburring the periphery of the threaded hole of the Dongbu sub-sub part, a part seating part 1200 for seating the part to be deburred, and a supporting housing (1300) supporting the part receiving part from the bottom. In the Dongbu Subbar deburring device made,
A nozzle 5000 for receiving air from an external air supply device and transferring it to a part seating unit;
A fixing bracket 7000 installed at one end of the support housing to fix the nozzle;
A fixing bolt (8000) for fixing the fixing bracket to the support housing;
Deburring device for processing the Dongbu subbar, characterized in that it comprises a long hole (9000) formed in the bracket for fixing to adjust the position of the bolt. The method of claim 1,
An air storage container 1000 installed at one end of the deburring device and storing air for supplying to the part seating unit;
An air supply means (2000) connected to the air storage container to receive and temporarily store air contained in the air storage container;
A control valve (4000) installed at one side of the output end of the air supply means to regulate air discharged to the nozzle;
Deburring device for processing the Dongbu bar, characterized in that it further comprises a footrest switch (6000) connected to one side of the air supply means to induce air supply by outputting an air supply switching signal. The method of claim 2,
It is formed between the air storage container and the air supply means further comprises an air outlet valve 100 for preventing reverse flow of air;
The air outlet valve,
An air output unit 10 formed by forming a first air flow pipe 11 through which air passes through one side and a first coupling pipe 12 formed at the other side;
A circular ring 21 formed to be inserted into the first coupling pipe and having a diameter smaller than the inner diameter of the first coupling pipe, a protrusion 22 formed inside the circular ring, and formed between the protrusions. Air passing means (20) made of an air flow hole (23);
A second coupling pipe 42 coupled to the inside of the first coupling pipe 12 of the air output unit 10 is formed on one side, and a second air flow pipe 41 through which air passes is formed on the other side. An air input unit 40 formed;
It is coupled to the inside of the second air flow pipe 41 and is temporarily coupled to the bypass disk 20 to induce air to flow through the first air flow pipe 11 of the air output unit 10, or A temporary blocking ball 30 temporarily coupled to the inlet of the second air flow pipe 42 of the input unit 40 to block the penetration of contaminants through the second air flow pipe 42;
A plurality of pieces are installed inside the second coupling pipe at regular intervals, and comprises a blocking ball guide means 50 for guiding the temporary blocking ball to move left and right without deviating from the horizontal center of the second coupling pipe. Deburring device for processing Dongbu subbar, characterized in that. The method of claim 1,
At one end of the deburring device, a contaminated air burner part 200 for burning contaminated air is further installed,
The contaminated air burner part,
A switching means 221 for supplying arc discharge electricity; Arc discharge re-ignition switching means 222 mounted on the switching means 221 for supplying arc discharge electricity to automatically re-ignite the arc discharge; A deburring device for processing a busbar, characterized in that the arc discharge re-ignition circuit unit 223 is connected to the arc discharge re-ignition switching means 222 and outputs a signal for re-ignitioning the arc discharge. The method of claim 4,
The arc discharge re-ignition switching means 222,
A pinion gear (222a) installed on the edge of the arc discharge electricity supply switching means (221) and rotating at the same time when the arc discharge electricity supply switching unit (221) rotates;
A first sliding transfer member (222b) formed by forming a rack gear (222e) on a contact surface with the pinion gear (222a) and having a cylindrical or square column shape so as to slide horizontally by rotation of the pinion gear (222a);
A second sliding transfer member (222c) coupled to the inner side of the first sliding transfer member (222b) and moving in conjunction with the first sliding transfer member (222b) when it moves to switch the arc discharge re-ignition circuit unit (223);
A tension spring (222d) connected to the end of the first sliding transfer member (222b) and the start of the second sliding transfer member (222b) and serving to maintain the switching state of the arc discharge re-ignition circuit unit (223). Deburring device for processing the eastern subbar, characterized in that consisting of. The method of claim 5,
The arc discharge re-ignition circuit unit 223,
A DC power supply unit 101 installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries or general batteries in series;
An arc discharge re-ignition switch 102 which has one end connected to the DC power supply and is switched on when the arc discharge re-ignition switching unit is rotated;
An oscillation boosting circuit part 103 for outputting a boosted AC current by supplying electricity when the arc discharge re-ignition switch is turned on;
A switching unit 108 for supplying electricity to a discharge electrode connected to the output terminal of the oscillation booster circuit unit and turned on by electric supply;
A high-voltage boosting circuit part 107 installed at an output terminal of the switching part for supplying electricity to the discharge electrode and generating a high voltage;
A high-pressure discharge spacer (113a, 113b) formed by connecting a high-voltage power supply supplied by the high-voltage booster circuit unit;
A discharge electrode 114 for inducing a flame to burn by igniting the discharge while being discharged using the power provided by the high-pressure discharge spacer;
The discharge electrode and the base end are connected, and the emitter end and the collector end are connected to the oscillation transformer and the switching unit for ignition of the discharge electrode. When the arc discharge flame is turned off by external wind or moisture, the closed circuit is broken due to the extinction of hot electrons and the switching is turned off. Accordingly, the power to the switching unit for supplying electricity to the discharge electrode is turned off. A deburring device for processing a busbar, comprising: a switching unit 118 for blocking a discharge electrode that functions to induce the discharge electrode to be ignited by turning it on.

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