JP3260259B2 - Flux circulatory system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flux circulator for recovering and reusing flux.

[0002]

2. Description of the Related Art Usually, during welding, powdery or granular flux is supplied to a welding position while a powdery or granular flux is supplied to a welding position so as to remove oxides and the like from a base material and a filler material to protect the surface of the base material. A flux circulator that collects and reuses used flux has been used.

Conventionally, the above-mentioned flux circulator, as shown in FIG. 2, comprises a hopper 51 for accommodating a flux, a filter 52 provided above the hopper 51, and air in the hopper 51 via the filter 52. System 57 that exhausts air by a blower 53, a suction system 54 that sucks the flux together with the air and introduces it into the hopper 51, and a collision plate 56 that decelerates the flux introduced via the suction system 54. I have. According to this configuration, the flux is collected by the hopper 51 via the suction system 54 and the
The flux is decelerated and dropped below the hopper 51, while only the air is discharged by the blower 53 through the filter 52 while capturing the dust, so that the flux can be collected and reused. I have.

[0004]

However, in the above-mentioned conventional configuration, there is a problem in that when the operation is stopped, moisture absorption of the flux which causes welding defects is likely to occur. That is,
During operation, the flux is reused while being dried by the welding heat, so that the flux does not absorb moisture to such an extent that welding defects are generated. However, when the operation is stopped, the exhaust system from the suction system 54 and the hopper 51 to the blower 53 is in an open state, so that external moist air enters the hopper 51 through these paths. . Therefore, the moisture absorption of the flux progresses with the passage of time, and the flux may absorb moisture to the extent that a welding defect is generated when the operation is resumed.If the humidity is high, the flux generates a welding defect overnight. It may absorb moisture to a certain degree.

In a cold season, the partition wall of the hopper 51 is rapidly cooled by the outside air, and dew forms on the inner wall of the hopper 51, so that the flux may absorb moisture. Further, since the filter 52 is disposed above the accommodated flux, dust having a strong hygroscopic activity falls from the filter 52 to the flux.
In this case, the dust is mixed into the flux, thereby promoting the moisture absorption of the flux, and the flux easily absorbs moisture even if the above-mentioned humid air or dew condensation is slight.

Therefore, Japanese Unexamined Utility Model Publication No. 59-49471 discloses a configuration in which a heater 58 is provided in a hopper 51 and the flux is heated by the heater 58 as shown in FIG. However, in this configuration, it is not possible to prevent dust from dropping into the flux or intrusion of moist air,
It is difficult to sufficiently prevent the flux from absorbing moisture.

Accordingly, an object of the present invention is to provide a flux circulator capable of sufficiently preventing the absorption of flux when the operation is stopped.

[0008]

In order to achieve the above object, according to the first aspect of the present invention, a first hopper for accommodating a flux and a first hopper connected in parallel to the first hopper for accommodating dust are provided. A second hopper, and a filter provided in the second hopper and passing only air while trapping dust, and exhausting the air from the filter through an exhaust system to remove used flux from the air. A flux circulator that collects and reuses the first hopper by sucking through the suction system together with the air, and the exhaust system and the suction system each include an air shutoff valve that can be closed in an airtight state. The first hopper is provided with a heater.

Further, the invention according to claim 2 is interlocked with the operating state of the flux circulator so that the air shutoff valve according to claim 1 is opened during operation and closed when operation is stopped. It is characterized by being controlled. The invention of claim 3 is characterized in that the heater of claim 1 is controlled to an arbitrary heating temperature.

[0010]

According to the first aspect of the present invention, since the air shutoff valves that can be closed in an airtight state are provided in the exhaust system and the suction system, these air shutoff valves are closed when the operation is stopped. Thus, it is possible to prevent the moist air from entering the first hopper and the second hopper via the exhaust system and the suction system. In addition, when the temperature of the outside air is low, the first hopper is heated by the heater, thereby preventing the dew condensation on the inner wall of the hopper. Further, since the filter is provided in the second hopper provided in parallel with the first hopper, even if the dust captured by the filter separates, the second hopper can be used.
It is dropped and stored in the hopper and does not mix with the flux stored in the first hopper.

As a result, the dust having a high adsorption activity does not promote the moisture absorption of the flux, and the humidity in the first hopper is kept low. Moisture absorption of the flux stored in the hopper can be sufficiently prevented.

According to the second aspect of the present invention, since the air shutoff valve is controlled in conjunction with the operation state of the flux circulator, the burden on the operator required to open and close the valve at the start and end of operation. Can be reduced. Further, according to the configuration of the third aspect, the first type is set according to the temperature of the outside air.
Since the hopper can be heated, excessive heat
It is possible to suppress an increase in operation cost due to the provision of the hopper.

[0013]

An embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 1, the flux circulator according to the present embodiment has a first hopper 1 that stores flux and a second hopper 2 that stores dust, which are connected in parallel.
The hopper 1 and the second hopper 2 are communicated via a communication port 3 formed in a side wall. At the upper part in the second hopper 2, a filter 4 for capturing dust and passing only air is provided.
Is provided, and the dust separated from the filter 4 is
It is accommodated in the second hopper 2 by natural fall.

A manual valve 6 is connected to the bottom of the second hopper 2 through an exhaust pipe 5 so as to be airtightly closed. The manual valve 6 is connected to the dust contained in the second hopper 2. Is used for discharging and stopping. On the other hand, an exhaust pipe 7 (exhaust system) connected to the inside of the filter 4 is connected to an upper portion of the side wall of the second hopper 2, and the exhaust pipe 7 is closed in an airtight state when the operation is stopped. A first automatic valve 8 (atmosphere shutoff valve) is provided. The exhaust pipe 7 is connected to a blower 9 (exhaust system). The blower 9 is connected to the inside of the second hopper 2 and the first hopper 1 via the first automatic valve 8, the exhaust pipe 7, and the filter 4. The inside air is sucked and discharged to the outside.

On the other hand, the first hopper 1 has an inlet 10a at an upper portion of a side wall facing the communication port 3. Inlet 1
0a is connected to a suction pipe 10 (suction system).
The suction pipe 10 is provided with a second automatic valve 11 (atmosphere shutoff valve) that is closed in an airtight state when the operation is stopped. The suction port 10b, which is the distal end of the suction pipe 10, is set at a position behind the welding point so as to suck and collect the flux together with the air. Also,
A collision plate 12 is provided on an upper wall in the first hopper 1 with an inlet 10.
The collision plate 12 is arranged vertically so as to face the first hopper 1, and the collision plate 12 collides the flux flowing into the first hopper 1 from the introduction port 10 a to reduce the flow velocity, so that the flux enters the first hopper 1. It is designed to fall naturally.

A supply pipe 14 whose supply port is set at a welding position is connected to the bottom of the first hopper 1.
The supply pipe 14 guides the flux stored in the first hopper 1 to the welding position by natural fall. An intermediate portion of the supply pipe 2 is provided with a manual valve 13 that can be closed in an airtight state. The manual valve 13 prevents the flux from dropping when the operation is stopped. Further, a heater 15 is joined to the inclined wall around the bottom of the first hopper 1 in a planar manner, and the heater 15 heats the partition wall of the first hopper 1. It is desirable that the heater 15 can be set to an arbitrary heating temperature by a temperature setting controller (not shown) so that the first hopper 1 can be heated according to the temperature of the outside air.

The operation of the flux circulator in the above configuration will be described. First, in the case of driving, by a driving instruction signal sent from a control device (not shown),
The first automatic valve 8 and the second automatic valve 11 are opened, and the blower 9 is operated.
As a result, the air in the second hopper 2 and the air in the first hopper 1 are exhausted, so that external air
Thus, the suction is performed from the suction port 10b.

Next, when the manual valve 13 is opened by the operator, the flux in the first hopper 1 is supplied to the welding position via the supply pipe 14. The flux acts to protect the surface of the base material by removing oxides and the like from the base material and the filler material during welding, and the remaining used flux is removed by air at a position behind the welding point. Will be sucked together.
The sucked flux flows into the first hopper 1 from the inlet 10a via the suction pipe 10, and then collides with the colliding plate 12 disposed opposite to the flux, so that the flow velocity is reduced. As a result, the flux falls naturally and is collected in the first hopper 1, and is again supplied to the welding position via the supply pipe 14.

On the other hand, the dust flowing into the first hopper 1 together with the flux has an extremely small specific gravity, so that the dust floats in the first hopper 1 and flows through the communication port 3 into the second hopper 2 with the flow of air. Will progress. Then, when the dust is captured by the filter 4 and then stacked in a predetermined amount or more, the dust falls into a lump and falls naturally and is stored in the second hopper 2. After this,
When it is determined that the stored amount has reached the predetermined amount or after the predetermined period has elapsed, the stored dust is discharged outside by opening the manual valve 6.

Next, when the operation is finished, the first command is sent by a stop command signal sent from control means (not shown).
The automatic valve 8 and the second automatic valve 11 are closed, and the blower 9 is stopped. At the same time, the manual valves 13.6 are also closed. Accordingly, the space inside the second hopper 2 and the space inside the first hopper 1 are shut off from the outside in an airtight state, so that the outside moist air does not enter.
Therefore, the flux does not cause the moisture absorption to progress with the passage of time, so that even if the operation is stopped for a long time, the welding does not cause a welding defect when the operation is restarted.

The controller measures the temperature of the outside air, and if it is determined that the temperature is lower than the temperature at which dew condensation occurs on the inner wall of the first hopper 1, the controller 15 operates the heater 15 to operate the heater 15. The partition of one hopper 1 will be heated. Thus, even in a cold season, the partition wall of the first hopper 1 is not rapidly cooled by the outside air, so that dew condensation on the inner wall does not occur. Further, as described in the above-described operation during the operation, the dust captured by the filter 4 is stored in the second hopper 2 by natural fall even when the operation is stopped, so that the dust is stored in the first hopper 1. Does not mix with flux. Therefore, the flux is
Moisture absorption is not promoted by dust having a strong hygroscopic activity.

When the first hopper 1 and the second hopper 2 of this embodiment are provided with an adjusting valve for adjusting the negative pressure, the adjusting valve is also provided with an air shutoff valve which can be hermetically closed. There is a need. By providing an atmosphere shutoff valve in the adjustment valve, it is possible to more completely prevent moist air from entering the hoppers 1 and 2. In the present embodiment, the first and second automatic valves 8 and 11 perform opening and closing operations in response to an operation instruction signal sent from a control device (not shown). A manual valve may be provided instead of 11 so that the operator can manually perform the opening and closing operation.

[0023]

According to the first aspect of the present invention, as described above, the first hopper for storing the flux, the second hopper connected in parallel to the first hopper and storing the dust,
A filter provided in the second hopper and passing only air while trapping dust, and exhausting the air from the filter through an exhaust system to remove the used flux together with the air to the suction system. A flux circulator that is collected by the first hopper and reused by suctioning through the exhaust system, wherein the exhaust system and the suction system include:
An air shutoff valve that can be closed in an airtight state is provided, and a heater is provided in the first hopper.

Thus, when the operation is stopped, by closing the atmosphere shutoff valve, it is possible to prevent the moist air from entering the first hopper and the second hopper via the exhaust system and the suction system. become. In addition, when the temperature of the outside air is low, the first hopper is heated by the heater, thereby preventing the dew condensation on the inner wall of the hopper. Furthermore, even if the dust captured by the filter separates, the dust falls and is stored in the second hopper and does not mix with the flux stored in the first hopper. Therefore, the dust having a strong adsorption activity does not promote the moisture absorption of the flux, and the humidity in the first hopper is kept low, so that the dust is stored in the first hopper even when the operation is stopped for a long time. This has the effect that moisture absorption of the generated flux can be sufficiently prevented.

Further, the invention of claim 2 is as described above,
The air shutoff valve according to claim 1 is controlled in conjunction with the operation state of the flux circulator so that the valve is opened during operation and closed when operation is stopped.

Thus, in addition to the effect of the first aspect, since the air shutoff valve is controlled in conjunction with the operation state of the flux circulator, the operation of the valve for opening and closing the valve at the start and end of operation is reduced. This has the effect of reducing the burden.

Further, the invention of claim 3 is as described above,
The heater according to claim 1 is configured to be controlled to an arbitrary heating temperature. Thus, the first hopper can be heated in accordance with the temperature of the outside air, so that an effect of suppressing an increase in operation cost due to applying an excessive amount of heat to the first hopper is exerted.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a flux circulator.

FIG. 2 is a schematic configuration diagram of a conventional flux circulator.

FIG. 3 is a schematic configuration diagram of a conventional flux recovery device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 1st hopper 2 2nd hopper 3 communication port 4 filter 5 discharge pipe 6 manual valve 7 exhaust pipe 8 1st automatic valve 9 blower 10 suction pipe 11 2nd automatic valve 12 collision plate 13 manual valve 14 supply pipe 15 heater

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Tetsuya Nakao 1-1-2 Nakahara, Miya-machi, Toyohashi-city, Aichi Prefecture Kobe Steel, Ltd. Toyohashi FA / Robot Center (56) References JP-A-61-249677 (JP) , A) JP-A-54-112749 (JP, A) JP-A-60-54278 (JP, A) JP-A-52-116963 (JP, A) Fully open 1984-49471 (JP, U) Really open 59-54174 (JP, U) Japanese Utility Model Showa 60-166472 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) B23K 9/18 B23K 25/00

Claims (3)

(57) [Claims] 1. A first hopper for storing a flux, a second hopper connected in parallel to the first hopper for storing dust, and a second hopper for storing dust, wherein the first hopper is provided in the second hopper and captures air while capturing dust. And a filter through which the first hopper includes a suction pipe having a suction port.
The second hopper has an exhaust pipe and
An exhaust system including a micro-blower is provided, the air from the filter by the exhaust through the exhaust system, the spent flux by sucking through the suction <br/>引系with air A flux circulator to be recovered and reused in the first hopper, wherein the exhaust pipe included in the exhaust system is hermetically sealed.
A possible air shutoff valve is provided to
The included suction pipe contains an air shield that can be closed in an airtight state.
A flux circulator, wherein a cutoff valve is provided, and a heater is provided in the first hopper. 2. The air shutoff valve is controlled in conjunction with the operation state of the flux circulator so that the air shutoff valve is opened when the operation is performed, and is closed when the operation is stopped. The flux circulator of claim 1. 3. The flux circulator according to claim 1, wherein the heater is controlled to an arbitrary heating temperature.