KR20130049366A - Ultrasonic bonding apparatus with air cooler - Google Patents

Abstract

PURPOSE: An ultrasonic melted welding device with an air cooling device is provided to prevent discoloration and deformation of synthetic resin or fabric by high fever and to prevent a substrate from affecting by cooling the ultrasonic melted welding device with dry air. CONSTITUTION: An ultrasonic melted welding device with an air cooling device comprises an ultrasonic melted welding device, a cooling device main body(200), a fixed bracket(300) in a ring shape, and an air injection hole(400) in a ring shape. The ultrasonic melted welding device includes an oscillator(120), a main horn(130), and a tool horn(140). The air injection hole in a ring shape is inserted from the front surface of the cooling device main body for preventing the oscillator from being separated at a constant interval. One or more penetration holes(410) for cooling air are formed at the edges of the air injection hole. A screw thread which is spirally connected to a screw groove(230) of the cooling device main body is formed on the outer circumference of the air injection hole.

Description

ULTRASONIC BONDING APPARATUS WITH AIR COOLER

The present invention relates to an ultrasonic melt bonding apparatus in which an air-cooling device is installed, and specifically, an ultrasonic fusion is performed by vibrating a vibrator, a main horn, or a tool horn due to heat generated by ultrasonic waves when bonding fabrics or synthetic resins using ultrasonic waves. Air cooling to control the temperature of the vibrator and main horn by air supply to adjust the temperature of the vibrator and main horn in order to prevent the device from malfunctioning or discoloration or deformation due to high temperature. The present invention relates to an ultrasonic melt bonding device in which an apparatus is installed.

Ultrasonic welding machine is a device that can quickly and efficiently bond thermoplastics and plastics, films, films, synthetic fibers, etc. using ultrasonic vibrations.

The ultrasonic welding machine fuses a vibrator for converting electrical energy generated from an oscillator into mechanical vibration, a main horn for amplifying mechanical vibration generated from the vibrator, and mechanical vibration amplified by the main horn, that is, ultrasonic vibration. It consists of a tool horn which generates friction heat in contact with a part of synthetic resin or fabric paper fixed to a pedestal.

Ultrasonic welding using such an ultrasonic welding machine includes spot welding, welding, inserting, staking, and the like. In particular, the welding method is the most widely used method of bonding two fibers, textile papers, or plastics, and a method of forming protrusions on a joint surface and then applying ultrasonic vibration to instantly melt the protrusions and bond them with other substrates.

In general, when joining two substrates using a large capacity ultrasonic welding machine, the protrusion formed on one substrate is melted by high frictional heat due to strong ultrasonic vibration, and the fluidity of the molten protrusion is excellent, and the adhesion between the substrates is also excellent. Do. However, when a special coating treatment or color layer is formed on the substrate, there is a problem that the defect of the product occurs due to a high frictional heat generated in the protrusion of the substrate, resulting in a defect of the product and an ultrasonic fusion due to high temperature heat. There is a problem that a tool horn, a main horn or a vibrator that is a component of the device is broken or broken.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

The present invention is due to the heat generated by the ultrasonic waves when bonding the fabric or synthetic resin, etc. using ultrasonic waves overheating the vibrator, the main horn or the tool horn due to the high temperature of the synthetic resin or textile paper that the ultrasonic welding device is to be broken or bonded It is an object of the present invention to provide an ultrasonic fusion bonding apparatus in which a cooling device is installed so as to prevent overheating generated by ultrasonic waves in order to prevent discoloration or deformation.

In order to solve the problems as described above, the ultrasonic melt bonding apparatus equipped with an air cooling apparatus according to the present invention is an oscillator for converting the electrical frequency generated from the oscillator supplied with external power to mechanical vibration, vibration of the vibrator Ultrasonic melt bonding apparatus consisting of a main horn for amplifying the tool horn and a tool horn mounted to the main horn to face the front horn to melt and fuse the portion to be bonded to the anvil by applying ultrasonic vibration; The oscillator is built with a certain clearance toward one side, the inner peripheral surface of one end is formed with a screw groove and a locking jaw in turn and the other side is opened one side is formed with an air inlet for supplying air from the outside A chiller body having a tubular structure; A ring-shaped fixing bracket which is fitted from one side of the cooling apparatus main body so that the oscillator is located inside the cooling apparatus main body, and at least one air supply hole is formed at an edge thereof; And a space between the fixing bracket and the oscillator so that the oscillator is not separated from the cooling apparatus main body, and is fitted from the front surface of the cooling apparatus main body, and at least one air cooling hole is formed at an edge thereof, It characterized in that it comprises a ring-shaped air injection port is formed on the outer circumferential surface of the screw thread that is helically coupled to the screw groove formed on the inner circumferential surface of one side end.

At this time, it is advantageous that the air supply through hole and the air cooling through hole are formed at positions corresponding to each other.

On the other hand, the air-cooled through-hole is preferably formed to be inclined toward the center from the edge of the air injection port, because the heat generated by the ultrasonic wave is the most damaging because the oscillator and the main horn to cool them by blowing air This is because it is necessary to indirectly cool the tool horn in order to prevent deformation or discoloration of the parts to be fused.

Therefore, the air exiting the inclined air-cooled through hole shows a lower temperature than the air supplied to the cooling apparatus body due to the throttling effect, and effectively cools the cooled air due to the throttling effect of the vibrator, main horn, and tool horn. In order to spray directly onto the surface, the air cooling through hole is preferably made in the form of a nozzle.

On the other hand, when a plurality of air-cooled through-holes are formed instead of one air-cooled through-holes, each air-cooled through-hole is formed to be inclined toward the center from the edge of the air injection port for each air-cooled through-hole to be different. Another feature is that the angles of inclination are different.

In addition, the present invention is characterized in that the air supply pipe connector made of a pipe form detachable to the air inlet further comprises a configuration. At this time, in order to maintain the coupling and detachment is convenient to process the screw groove is formed around the air inlet, the screw coupling is formed corresponding to the screw groove formed around the air inlet on the outer peripheral surface of one side end of the air supply pipe connector It is desirable to have a screw groove as possible. On the other hand, it is preferable to form a screw groove so that the outer circumferential surface of the other end of the air supply pipe connector can be screwed with the connection hose and the like supplied from the air supply device.

The present invention is due to the heat generated by the ultrasonic waves when bonding the fabric or synthetic resin, etc. using ultrasonic waves overheating the vibrator, the main horn or the tool horn due to the high temperature of the synthetic resin or textile paper that the ultrasonic welding device is to be broken or bonded It has the advantage that it can prevent discoloration or deformation caused by defects.

In addition, the present invention does not affect the substrate because the ultrasonic melt bonding apparatus can be cooled by dry using dry air instead of wet using water, and it is possible to simply configure an air cooling apparatus even when only an air compressor or an air supply is connected. Another advantage is that it can be useful and useful.

Figure 1 shows the overall configuration of the ultrasonic melt bonding apparatus is installed air cooling apparatus according to the present invention.
Figure 2 shows a cross section of the ultrasonic melt bonding apparatus is attached to the air cooling apparatus according to the present invention.
Figure 3 shows a cross section of the fixing bracket of the components of the present invention.
Figure 4 shows a cross section of the air injection port of the components of the present invention.

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

Figure 1 shows the overall configuration of the ultrasonic melt bonding apparatus is installed air cooling apparatus according to the present invention, Figure 2 is a cross-sectional view of the ultrasonic melt bonding apparatus is installed air cooling apparatus according to the present invention.

Ultrasonic melt bonding apparatus 100 is an oscillator 110, a vibrator 120. The main horn 130, the tool horn 140, and the power supply line 150 are configured to generate vibrations by converting the electrical frequency generated from the oscillator 110 into mechanical frequency by the power supplied through the power supply line. When generated, the main horn 130 for amplifying the vibration of the vibrator 120 and the ultrasonic vibration transmitted from the main horn are transmitted through the tool horn 140 to melt and fuse the portion to be bonded to the anvil. . At this time, the vibrator 120 and the main horn 130 are coupled using a fastening bolt, and the main horn 130 and the tool horn 140 are integrally formed.

On the other hand, the oscillator 110 is built in the cooling device main body 200 of the tubular structure in which one side is opened and the air inlet 210 is formed on the other side, with a constant distance from the cooling device main body 200 It is fixedly installed. And the oscillator is fixed through the fixing bracket 300 and the air injection port 400 is screwed with the main body screw groove 230 formed in the cooling device body 200 so that the oscillator is not separated from the role is fixed firmly Will be in charge. At this time, the fixing bracket 300 is fixed to the ultrasonic melt bonding device 100 in a state that is stably over the inside of the cooling device main body by the locking projection 240 for the bracket formed on the inner peripheral surface of the opening of the cooling device main body 200, The air injection port 400 is spaced apart from the fixing bracket 300 by being coupled to the main body screw groove 230 formed on the inner circumferential surface of the opening of the cooling apparatus main body 200 through screwing. At this time, the air injection port screw groove 420 formed along the outer circumferential surface of the air injection port corresponds to the main body screw groove 230 to be screwed.

The cold air supplied through the air inlet 210 of the chiller main body 200 fills the empty space formed between the chiller main body and the oscillator, thereby primarily cooling the oscillator 110. Afterwards, the cold air filled in the empty space inside the cooling device is discharged through the air supply through hole 310 formed in the fixing bracket 300 again, and the cooling air is faster due to the throttling effect and the speed is increased. As it exits through the air-cooling through-hole 410 formed in the air injection port 400, it is additionally cooled due to the throttling effect and at the same time, the air outflow rate is also faster.

In this case, in order to smoothly move the air, it is preferable that the positions of the air supply hole 310 and the air cooling hole 410 correspond to each other, but between the fixed bracket 300 and the air injection port 400. Since there is a certain clearance, even though the position of the air supply hole 310 and the location of the air cooling hole 410 correspond to each other, there is a slight time difference, but the cooling air is fixed to the fixing bracket 300. Filling the clearance gap formed between the air injection port 400 can be sufficiently communicated due to the difference in air pressure can be injected to the outside through the air injection port.

At this time, according to the inclination angle of the air-cooled through-hole 410 is blown cold air for each of the vibrator 120, the main horn 130, the tool horn 140 due to the heat generated by the ultrasonic vibration by air cooling It is possible to prevent the temperature from rising. In fact, the heat generated by the ultrasonic vibration causes the temperature of the main horn, the tool horn and the vibrator to reach about 70 ° C. If left without air cooling, the main horn or the tool horn as well as the vibrator may cause malfunction or failure. Becomes Therefore, when the air cooled by the cooling device according to the present invention using the cold air to each component can drop the temperature of each component of the ultrasonic melt bonding apparatus to a safe temperature of 40 ℃.

On the other hand, the cooling air is to use the compressed air provided by the compressor or the air supply compressor from the outside, in this case is inserted into the air inlet of the cooling device body 200 for convenience using a removable air supply pipe connector (500) It is good. The outer circumferential surface of one side end of the air supply pipe connector 500 is formed with a screw groove that can be screwed in correspondence with the screw groove formed around the air inlet 210, so that the air supply pipe connector 500 through the screw coupling and release It is possible to install and detach the air inlet 210.

Figure 3 shows a cross section of the air injection port of the components of the present invention.

Air injection port 400 is configured in the form of a thin coin, the center of the through hole is formed so that the oscillator 120, the main horn 130 and the tool horn 140 of the ultrasonic melt bonding apparatus to the outside while the cooling device body ( 200).

At this time, it is preferable that a plurality of air cooling through holes 410 are formed around the through hole of the air injection port 400. The air cooling through holes 410 may be inclined toward the center from the edge. Normally it can be inclined to 10 ~ 60 ° toward the center with respect to the horizontal, the air cooling through-hole 410 is preferably configured in the form of a nozzle in order to speed up the air flow.

On the other hand, the angle of inclination of the plurality of air-cooled through-holes 410 may be formed differently in order to evenly cool the respective parts of the ultrasonic melt bonding device.

In addition, the air injection port screw groove 420 is formed on the outer circumferential surface of the air injection port corresponding to the main body screw groove 230 formed on the inner surface of the opening of the cooling device main body 200 to be screwed.

100: ultrasonic melt bonding device
110: oscillator 120: oscillator
130: main horn 140: tool horn
150: power supply line
200: cooling device body
210: air inlet 220: power supply line through
230: main body screw groove 240: bracket jaw
300: fixed bracket
310: through air supply
400: air jet
410: air cooling through-hole 420: air injection port screw groove
500: air supply pipe connector

Claims (7)

An oscillator for converting an electrical frequency generated from an externally powered oscillator into mechanical vibration, a main horn for amplifying the vibration of the vibrator, and a main joint mounted on the main horn facing the front and applied to the anvil and placed in anvil Ultrasonic melt bonding apparatus consisting of a tool horn for melting and fusion to be part;
The oscillator is built with a certain clearance toward one side, the inner peripheral surface of one end is formed with a screw groove and a locking jaw in turn and the other side is opened one side is formed with an air inlet for supplying air from the outside A chiller body having a tubular structure;
A ring-shaped fixing bracket which is fitted from one side of the cooling apparatus main body so that the oscillator is located inside the cooling apparatus main body, and at least one air supply hole is formed at an edge thereof; And
The oscillator is fitted from the front surface of the cooling apparatus main body so that the oscillator is separated from the cooling apparatus main body with a predetermined clearance from the fixing bracket, and at least one air cooling through-hole is formed at an edge thereof, and an outer circumferential surface of one side of the cooling apparatus main body is provided. Ultrasonic melt bonding apparatus with an air-cooling device, characterized in that it comprises a ring-shaped air injection port is formed on the outer peripheral surface of the screw thread that is coupled to the screw groove formed on the inner peripheral surface of the stage. In claim 1,
The air supply hole and the air-cooled through-hole is an ultrasonic melt bonding apparatus with an air-cooling device, characterized in that formed in a position corresponding to each other. In claim 1,
The air-cooled through-holes are ultrasonic melt bonding apparatus with an air-cooling device, characterized in that formed inclined toward the center from the edge of the air injection port. 4. The method of claim 3,
The air-cooled through-hole is an ultrasonic melt bonding device is installed air cooling device, characterized in that consisting of a nozzle. The method of claim 3 or 4,
And a plurality of air cooling holes, wherein the inclination angles of the air injection holes are different for each air cooling hole. In claim 1,
Ultrasonic melt bonding device is installed air-cooling device, characterized in that the air inlet pipe connector made of a pipe form detachable to the air inlet further comprises a configuration. The method of claim 6,
A screw groove is formed around the air inlet,
Ultrasonic melt bonding apparatus with an air-cooling device is installed on the outer circumferential surface of one end of the air supply pipe connector is formed with a screw groove corresponding to the screw groove formed around the air inlet.

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