KR200327886Y1 - structure of welding machine - Google Patents

Abstract

The present invention relates to a damage preventing structure of a welder circuit, and more particularly made of metal, a plurality of through-holes are formed on the side, the circuit is located on the top heat sink that receives the heat generated by the circuit ( 10); A fan 20 attached to one side of the heat sink 10 so that air passing through the through hole of the heat sink 10 flows to the outside of the case to discharge heat of the heat sink 10 to the outside; An inlet 30 formed of a plurality of through holes formed in the case corresponding to the through holes of the heat sink 10; An exhaust port 40 formed of a plurality of through holes formed in the case corresponding to the fan 20; And a packing 50 located between one side of the heat sink 10 and the inlet port 30 and the fan 20 and the exhaust port 40 to seal the inside of the case. A damage prevention structure of a circuit is provided.

In addition, the temperature sensor is installed on one side of the circuit to sense the temperature of the circuit; A level meter 70 installed on one side of the case to display a temperature; A buzzer 80 generating a warning sound; A controller (90) connected to the temperature sensor (60) to receive a measurement of the temperature sensor (60) and to control the level meter (70), the buzzer (80) and a power control unit according to the measurement value; And a bimetal 100 which is installed at one side of the circuit and is deformed according to the temperature of the circuit and outputs a signal to the power control unit to cut off the power at a high temperature. It is about.

Accordingly, there is an advantage that the heat generated in the circuit inside the welder is easily cooled, and the inside of the case is sealed to prevent damage caused by inflow of dust, moisture, and the like. In addition, it is easy to check the temperature state inside the welding machine, it is easy to check the user when the overheat occurs, there is an advantage that the power is automatically cut off to prevent circuit damage due to heat.

Description

Structure of welding machine damage prevention {structure of welding machine}

The present invention prevents foreign substances from entering the inside while easily cooling the welding machine, thereby preventing damage, displaying the internal temperature, generating a warning sound when overheating, and automatically shutting off the power to prevent damage to the circuit. A damage prevention structure of the welder circuit.

The circuit provided inside the welder generates heat during use, and when the temperature inside the welder rises due to the heat, the elements in the circuit deteriorate and are damaged when overheated.

In order to prevent the temperature rise inside the welding machine, a heat sink made of metal having high thermal conductivity is provided on one side of the circuit, and a fan is attached to the heat sink to circulate air to cool the circuit. At this time, a plurality of through-holes should be formed in the case to receive the cold air outside and to discharge the hot air inside. However, when a plurality of through holes are formed in the case as described above, there is a problem that damage may occur when foreign substances are introduced through the through holes. In particular, the welding machine is used at the production site or construction site, so there is a lot of dust and moisture, which may cause an accident such as a fire or an electric leakage.

In addition, even if the heat sink and the fan is provided as described above, since the temperature may continue to increase, damage by overheating may occur. In order to solve this problem, conventionally, a bimetal is installed on one side of the circuit, and the bimetal is connected to an input side of a power circuit so that the power is cut off by the operation of the bimetal when the internal temperature exceeds a predetermined temperature. In addition, in this case, the warning light is turned on so that the user can check, but there is a problem that it is difficult to check before the operator sees the welder. In addition, since it is difficult for an operator to grasp the state of the welding machine in advance, there is a problem that the overheat occurs only when the welding is impossible because the power is cut off by the operation of the bimetal.

An object of the present invention is to provide a damage preventing structure of a welder circuit, which is devised to solve the above problems and prevents damage caused by inflow of dust, moisture, and the like.

And it is another object to provide a damage prevention structure of the welding machine circuit can easily check the temperature state inside the welding machine, easy to check the user when the overheat occurs, the power is automatically cut off.

1 is an assembled perspective view of a welding machine according to an embodiment of the present invention.

<Description of Symbols Used in Main Parts of Drawing>

10: heat sink 20: fan

30: intake port 40: exhaust port

50: packing 60: temperature sensor

70: level meter 80: buzzer

90 controller 100 bimetal

The present invention is made of a metal to achieve the above object, a plurality of through-holes are formed on the side, the circuit is located on the top of the heat sink to receive the heat generated by the circuit; A fan 20 attached to one side of the heat sink 10 so that air passing through the through hole of the heat sink 10 flows to the outside of the case to discharge heat of the heat sink 10 to the outside; An inlet 30 formed of a plurality of through holes formed in the case corresponding to the through holes of the heat sink 10; An exhaust port 40 formed of a plurality of through holes formed in the case corresponding to the fan 20; And a packing 50 located between one side of the heat sink 10 and the intake port 30 and the fan 20 and the exhaust port 40 to seal the inside of the case. .

And a welding machine provided with a circuit inside the case to supply power to the welding apparatus, the temperature sensor being installed at one side of the circuit to sense the temperature of the circuit; A level meter 70 installed on one side of the case to display a temperature; A buzzer 80 generating a warning sound; A controller (90) connected to the temperature sensor (60) to receive a measurement of the temperature sensor (60) and to control the level meter (70), the buzzer (80) and a power control unit according to the measurement value; And a bimetal 100 which is installed at one side of the circuit and deforms according to the temperature of the circuit and outputs a signal to the power control unit to cut off power at a high temperature.

Hereinafter, with reference to the accompanying drawings will be described in detail the damage prevention structure of the welder circuit according to an embodiment of the present invention.

The damage preventing structure of the welder circuit according to an embodiment of the present invention is composed of a heat sink 10, a fan 20, an intake port 30, an exhaust port 40 and the packing 50. In addition, the temperature sensor 60, the level meter 70, the buzzer 80, the controller 90 and the bimetal 100 will be included.

First, the heat sink 10 will be described. The heat sink 10 receives heat generated from the inside of the welder and serves to lower the temperature of the circuit. The heat sink 10 is made of a relatively high thermal conductivity metal, such as aluminum. A plurality of through holes are formed side by side on the heat sink 10. Air flows through the through hole to easily cool the heat of the heat sink 10. Since the technology related to the heat sink 10 to lower the temperature of the circuit as described above is a technique for the main pipe in the art, detailed description thereof will be omitted.

Next, the fan 20 will be described. The fan 20 is rotated when the power is supplied to flow air to one side. The fan 20 is attached to a side surface of the heat sink 10 through which the through hole is formed to discharge the air introduced through the through hole of the heat sink 10 to the outside. Here, when the fan 20 and the heat sink 10 are coupled, it is preferable that the air inside the case is not introduced into the coupling portion of the fan 20 and the heat sink 10. This is to block the inside of the case and the heat sink 10 and the outside of the case.

Next, the intake port 30 will be described. The intake port 30 is composed of a plurality of through holes formed on one side of the case. One side of the through hole of the heat dissipation plate 10 is positioned in the intake port 30, and the fan 20 is operated to introduce external air through the intake port 30.

Next, the exhaust port 40 will be described. The exhaust port 40 is composed of a plurality of through holes formed on one side of the case. One side of the fan 20 is positioned in the exhaust port 40 to pass through the through hole of the heat sink 10 to discharge the heated air to the outside.

Next, the packing 50 will be described. The packing 50 is made of synthetic rubber and is sealed between the edge of the inlet port 30 and the edge of the heat sink 10. In addition, the packing 50 is located between the edge of the exhaust port 40 and the edge of the fan 20 to be sealed. The reason for sealing by using the packing 50 as described above is that foreign matters such as dust and moisture are introduced into the interior according to the inflow of air generated by the operation of the fan 20 to cause short, fire, etc. to be accumulated in the circuit. To prevent this. That is, the outside air flows in through the inlet port 30, passes through the heat sink 10 and the fan 20, and exits the exhaust port 40, thereby preventing the air from entering the other space inside the case.

The temperature sensor 60 will be described. The temperature sensor 60 is located on one side of the circuit to measure the temperature of the circuit. In this embodiment, the temperature sensor 60 is configured to be located on the side of an IGBT (Insulated Gate Bipolar Transistor). This is because the idleness generates a lot of heat. As described above, the temperature sensor 60 generates a voltage in accordance with the ambient temperature, and thus, a detailed description thereof will be omitted since it is a technology for a main pipe in the art.

Next, the level meter 70 will be described. The level meter 70 is a device for displaying the strength of the input signal. In the present embodiment is installed in the front of the case and a plurality of LEDs are arranged in a row in a vertical line, the predetermined number of LEDs are turned on according to the temperature measured by the temperature sensor 60, the user can determine the current temperature inside the welder. It is configured to be. However, it is not limited to the LEDs arranged in a line as above. It may be displayed as a digital value or an analog type with a display needle.

The buzzer 80 is installed at one side of the case, and generates a sound when a signal is input.

Next, the controller 90 will be described. The controller 90 is connected to the temperature sensor 60 to receive a signal generated by the temperature sensor 60. The controller 90 analyzes the signal of the temperature sensor 60 and generates a signal for operating the level meter 70 according to the temperature of the circuit so that the temperature is displayed through the level meter 70. .

In addition, when the temperature of the circuit exceeds a predetermined temperature (for example, 80 degrees Celsius) is configured to transmit a signal to the buzzer 80 to generate a warning sound. When the temperature of the circuit continues to rise and enters a dangerous state (for example, 100 degrees Celsius or more), the controller 90 outputs a signal to cut off power to the power controller to prevent damage to the circuit.

Next, the bimetal 100 will be described. The bimetal 100 combines two metals having different expansion coefficients. The bimetal 100 is installed at one side of the circuit and a power line is connected. It is configured to separate the contact when it overheats and enters the dangerous state. This is to prevent damage to the circuit by cutting off the power by the bimetal 100 when the controller 90 does not shut off the power due to a failure or the like in a dangerous state.

Hereinafter will be described the operation of the damage prevention structure of the welder circuit according to an embodiment of the present invention.

When the welding operation is performed while the welding machine is turned on, the internal temperature gradually increases as the circuit of the welding machine generates heat. The heat of the circuit is transferred to the heat sink 10 located below the circuit. The heat transferred to the upper portion of the heat sink 10 is spread through the heat sink 10 and cooled by cold air introduced from the outside of the case by the action of the fan 20 provided on one side of the heat sink 10. do. At this time, foreign matter such as dust is introduced along the air, but is prevented from being introduced into the sealed case by the packing 50. This prevents dust from accumulating in the circuit inside the case.

When the temperature of the circuit rises by the welding operation, the temperature sensor 60 located next to the idle will sense the temperature of the idle and generate a voltage and transmit it to the controller 90. The controller 90 determines the temperature according to the voltage and transmits a signal to the level meter 70. Accordingly, the level meter 70 turns on the LED to display the temperature inside the welder.

If the heat generated in the circuit exceeds the cooling capacity by the heat sink 10 and the fan 20, the temperature inside the welder continues to rise. Accordingly, the voltage generated by the temperature sensor 60 continues to rise, and the controller 90 receiving the voltage sends a signal to the buzzer 80 when the voltage is greater than 80 degrees Celsius so as to sound an alarm. When the temperature is 100 degrees Celsius, the controller 90 outputs a signal to the power control circuit so that the power control unit cuts off power to prevent damage to the circuit. At this time, if the controller 90 does not cut off the power supply due to a failure, the temperature continues to rise and the bimetal 100 outputting a signal to the power control unit operates to cut off the power by the power control unit.

Accordingly, there is an advantage that the heat generated in the circuit inside the welder is easily cooled, and the inside of the case is sealed to prevent damage caused by inflow of dust, moisture, and the like. In addition, it is easy to check the temperature state inside the welding machine, it is easy to check the user when the overheat occurs, there is an advantage that the power is automatically cut off to prevent circuit damage due to heat.

Claims (2)

In the case of the structure that the plurality of through-holes are formed and the flow of air is made and the circuit is provided inside the case to supply a stable power to the welding device, A heat dissipation plate 10 formed of metal and having a plurality of through-holes formed at a side thereof, such that the circuit is positioned at an upper portion thereof to receive heat generated by the circuit; A fan 20 attached to one side of the heat sink 10 so that air passing through the through hole of the heat sink 10 flows to the outside of the case to discharge heat of the heat sink 10 to the outside; An inlet 30 formed of a plurality of through holes formed in the case corresponding to the through holes of the heat sink 10; An exhaust port 40 formed of a plurality of through holes formed in the case corresponding to the fan 20; And a packing 50 located between one side of the heat sink 10 and the inlet port 30 and the fan 20 and the exhaust port 40 to seal the inside of the case. Damage prevention structure of the circuit. In the welding machine provided with a circuit inside the case to supply power to the welding device, A temperature sensor (60) installed at one side of the circuit to sense the temperature of the circuit; A level meter 70 installed on one side of the case to display a temperature; A buzzer 80 generating a warning sound; A controller (90) connected to the temperature sensor (60) to receive a measurement of the temperature sensor (60) and to control the level meter (70), the buzzer (80) and a power control unit according to the measurement value; And a bimetal 100 which is installed at one side of the circuit and is deformed according to the temperature of the circuit to output a signal to the power control unit to cut off the power at a high temperature. .