JPH0823161A - Reflow device - Google Patents

Abstract

PURPOSE:To suppress inert gas flow from a furnace main body by mounting a labyrinth at the entrance and exit of the furnace permitting free vertical movement so as to vertically face one another by sandwiching a conveyer and vertically moving it to a position corresponding to the mounting height of parts on the printed board passing through the entrance and exit of the furnace. CONSTITUTION:When a printed board 1 comes close to the furnace entrance 11, a sensor 25 detects information of the mounting height of a mounting component. When a control part 30 catches such information, an actuator 41 is driven, and a top labyrinth 21-1 on the furnace entrance 11 is permitted to ascend or descend to a position that corresponds to the mounting height of the highest mounting component 2B. Therefore, the printed board 1 is carried into an atmosphere furnace main body 10 through the vertically small space between the top and bottom labyrinths 21-1 and 21-2 and the furnace entrance 11. When the printed board 1 comes close to the furnace exit after reflow soldering, a sensor 26 detects in the same manner, and a top labyrinth 21-2 is controlled to position according to the mounting height of the highest mounting component 2B.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used when mounting components by reflow soldering on a printed wiring board.
Reflow device

[0002]

2. Description of the Related Art A conventional reflow apparatus is shown in FIGS.
In the figure, 1 is a printed wiring board on which mounting components 2A and 2B having different heights are surface-mounted by reflow soldering.

Reference numeral 10 denotes a preheating chamber which is maintained at about 180 ° C., a main heating chamber which is maintained at about 250 ° C., a slow cooling chamber for gradually lowering the temperature of the printed wiring board, and a conveyor 5 It is an atmosphere furnace body in which parts other than the vertical runway are partitioned by partition walls. The preheating chamber, main heating chamber, and slow cooling chamber are heated by respective heaters (not shown).

The reflow apparatus is provided with a conveyor (for example, a chain conveyor) 5 that runs horizontally in the atmosphere furnace main body 10, and the printed wiring board 1 is conveyed by the conveyor 5.
Is heated to the solder melting temperature (about 240 ℃), the creamy solder that is printed and applied on the pads arranged on the printed wiring board 1 is reflowed, and the leads or electrodes of the mounted components 2A and 2B are connected to the pads and pads. The components are surface-mounted on the printed wiring board 1 by soldering.

Such a reflow device is required to contain an inert gas (generally nitrogen gas is used) having a constant concentration in order to prevent the printed wiring board 1 and the solder from being oxidized.

For this purpose, nitrogen gas is supplied into the atmosphere furnace main body 10 through the nitrogen gas supply pipe 8. The atmosphere furnace body
A sensor for detecting the nitrogen gas concentration is installed in the chamber 10, and the opening / closing valve provided in the nitrogen gas supply pipe 8 is automatically opened / closed based on the detection value of the sensor to control the nitrogen gas concentration in the atmosphere furnace body 10. It is kept at a predetermined concentration.

A fan (not shown) is attached to each of the preheating chamber, the main heating chamber and the slow cooling chamber so that each chamber is made uniform to a predetermined temperature and nitrogen gas is blown onto the printed wiring board 1. .

In such a reflow apparatus, a furnace inlet 11 for loading the printed wiring board 1 and a furnace outlet 12 for discharging the printed wiring board 1 are opened in a frame shape. Furnace inlet 11, furnace outlet
The height of the opening of 12 (width in the vertical direction) is such a height that the printed wiring board 1 on which the mounting component with the highest mounting height is mounted can pass, and the height of the openings of the furnace inlet 11 and the furnace outlet 12 is Is larger than the width of the conveyor 5 (larger than the width of the printed wiring board 1).

Since the opening areas of the furnace inlet 11 and the furnace outlet 12 are large in this way, nitrogen gas flows out from the furnace inlet 11 and the furnace outlet 12, and the concentration of nitrogen gas in the atmosphere furnace body 10 is reduced within a short time. descend. Therefore, the nitrogen gas is continuously and automatically replenished from the nitrogen gas supply pipe 8.

As a measure for preventing the outflow of nitrogen gas, conventionally, a long rectangular tubular body 15 communicating with the preheating chamber so as to project to the front of the atmosphere furnace main body 10 is attached to the furnace inlet 11, and at the rear of the atmosphere furnace main body 10. Attach a long rectangular tube 15 that communicates with the slow cooling chamber to the furnace outlet 12 so that it projects,
I made it difficult for nitrogen gas to flow out from 12.

The cross-sectional shapes of these rectangular cylinders 15 are equal to the frame shapes of the furnace inlet 11 and the furnace outlet 12.

[0012]

However, in the conventional reflow apparatus, the height of the opening of the rectangular tubular body is increased so that the printed wiring board on which the mounted components of all mounting heights are mounted can pass through. Is.

For this reason, when printed wiring boards on which mounting components having a low mounting height are mounted are continuously reflow-soldered, the outflow amount of nitrogen gas increases and the usage amount increases, resulting in a running cost of the reflow device. There was a problem that it would increase.

The present invention has been made in view of the above points, and an object thereof is to provide a reflow apparatus in which the outflow of an inert gas is small and the running cost is low.

[0015]

In order to achieve the above-mentioned object, the present invention, as illustrated in FIG. 1, includes an atmosphere furnace main body 10 filled with an inert gas and kept at a predetermined temperature,
In a reflow device that conveys the printed wiring board 1 using a horizontally running conveyor 5 and reflow-solders the mounted components on the printed wiring board 1, the conveyor 5 is sandwiched in front of the furnace inlet 11 of the atmosphere furnace body 10. A pair of upper and lower labyrinths 21-1 and 21-2 mounted so as to face each other vertically, and a pair of upper and lower labyrinths mounted on the rear surface side of the furnace outlet 12 of the atmosphere furnace body 10 so as to face each other with the conveyor 5 interposed therebetween. Upper / lower labyrinth 22
-1,22-2 and.

Further, actuators 41 and 42 for moving up and down at least the upper labyrinths 21-1 and 22-1 on the furnace inlet 11 side and the furnace outlet 12 side, and a transfer sequence storage circuit for the printed wiring board in the atmosphere furnace body 10 And a control unit 30 for controlling the actuators 41 and 42.

Further, one sensor 25, which is installed in front of the furnace inlet 11 and detects information about the mounting height of the mounted components of the printed wiring board 1, and the printed wiring board 1 installed in the atmosphere furnace body 10, The other sensor 26 for detecting that the furnace outlet 12 is approached.

The control unit 30 controls the upper and lower labyrinths 21-1 and 21-2 on the furnace inlet 11 side based on the detection information of one sensor 25.
It shall be raised and lowered to the position corresponding to the mounting height of the mounted components. Further, the control unit 30 moves the upper and lower labyrinths 22-1 and 22-2 on the side of the furnace outlet 12 up and down to the position corresponding to the mounting height of the mounted components based on the detection information of the other sensor 26.

As illustrated in FIG. 4, it is assumed that the sensor installed on the furnace inlet 11 side is an optical sensor 60 for detecting the mounting height of the highest mounted component mounted on the printed wiring board 1. As illustrated in FIG. 5, a barcode 70 indicating the model number of the printed wiring board 1 is attached to the printed wiring board 1, and the sensor installed on the furnace inlet 11 side is a barcode reader 65 that reads the barcode 70. And

The control unit 30 has a memory 31 in which the mounting heights of the highest mounted components to be mounted on the printed wiring boards of all model numbers are recorded, and based on the information read from the memory 31, the upper and lower labyrinths. 21-1, 21-2, 22-1, 22-2 shall be moved up and down as required.

Alternatively, the control unit 30 has a memory in which the mounting heights of the highest mounted components to be mounted on the printed wiring board of that model number are classified and recorded in a plurality of levels. And
Based on the level read from the memory, the upper and lower labyrinths 21-1, 21-2, 22-1, 22-2 are moved up and down in a predetermined manner.

As shown in FIG. 6, a bar code 71 indicating a magazine number is attached to a magazine 75 containing a plurality of printed wiring boards 1A and 1B, and the sensor installed on the furnace inlet 11 side is A bar code reader that reads the bar code 71 is used.

The control unit 30 records the model numbers and the order of accommodation of the printed wiring boards 1 accommodated in all magazines,
Moreover, it has a memory in which the mounting height of the highest mounted component is classified into multiple levels and recorded. Based on the levels read from that memory, the upper and lower labyrinths 21-1, 21-2, 22-1, 22- 2 shall be raised and lowered as required.

As shown in FIG. 7, the actuator is a fluid cylinder 80 which moves the upper and lower labyrinths up and down to two high and low positions. The control unit 30 has mounting heights of the highest mounted components mounted on the printed wiring boards of all model numbers,
It has a memory that is classified and recorded in two levels.

Then, it is assumed that the upper and lower labyrinths 21-1, 21-2, 22-1, 22-2 are moved to either the high or low position based on the level read from the memory.

[0026]

In the labyrinth, a large number of fins are arranged in a comb shape on the seat plate to increase the resistance to the flow of the inert gas.

According to the present invention, such a labyrinth is vertically movably mounted on a furnace inlet and a furnace outlet so as to face each other with a conveyor interposed therebetween, and is mounted on a printed wiring board passing through the furnace inlet and the furnace outlet. It is raised and lowered to the position corresponding to the mounting height.

Therefore, the outflow of the inert gas in the atmosphere furnace body is suppressed, and the running cost is reduced.

[0029]

The present invention will be described in detail with reference to the drawings. The same reference numerals indicate the same objects throughout the drawings.

FIG. 1 is a block diagram of a reflow apparatus according to the present invention,
FIG. 2 is a front view of the reflow apparatus of the present invention, and FIG. 3 is a perspective view showing an example of the labyrinth. 4 is a perspective view of an essential part of an embodiment of the invention of claim 2, FIG. 5 is a configuration diagram of the invention of claim 3, and FIG. 6 is a perspective view of a magazine according to the present invention.
FIG. 7 is a perspective view of an essential part of the invention of claim 6.

As shown in FIGS. 1 and 2, the atmosphere furnace body
Inside the 10 furnaces, there are a pre-heating chamber that is maintained at approximately 180 ° C, a main heating chamber that is maintained at approximately 250 ° C, and a slow cooling chamber that gradually lowers the temperature of the printed wiring board. Parts other than the horizontal vertical runway are divided by partition walls.

The preheating chamber, main heating chamber, and slow cooling chamber are heated by respective heaters (not shown) or far infrared rays, and
An inert gas such as nitrogen gas is supplied into the atmosphere furnace main body 10 through the nitrogen gas supply pipe 8.

A sensor for detecting the nitrogen gas concentration is mounted in the atmosphere furnace main body 10, and the opening / closing valve provided in the nitrogen gas supply pipe 8 is automatically opened / closed based on the detection value of this sensor to change the atmosphere furnace. The nitrogen gas concentration in the main body 10 is maintained at a predetermined concentration.

Reference numeral 1 denotes a printed wiring board which is conveyed into the atmosphere furnace body 10 by the conveyor 5 and surface-mounted by reflow soldering the mounted components. The mounted components 2A, 2B ,. ..Mounting height is different, and mounting component 2B shown in the figure has the largest mounting height.

A pair of upper and lower labyrinths 21-1, 21-2 are mounted on the front side of the furnace inlet 11 of the atmosphere furnace body 10 so as to face each other with the conveyor 5 interposed therebetween. Further, a pair of upper and lower labyrinths 22-1 and 22-2 are mounted on the rear surface side of the furnace outlet 12 of the atmosphere furnace main body 10 so as to face each other with the conveyor 5 interposed therebetween.

An example of such a labyrinth is shown in FIG. The labyrinth shown in FIG. 3 is a lower labyrinth 21-2, which is made of a metal such as aluminum or a synthetic resin, and has a large number of fins 21B formed in a comb shape on the surface of the seat plate 21A so as to be orthogonal to the traveling direction of the conveyor 5. It is arranged in.
The fins 21B have a width of about 2 mm, an arrangement interval of about 10 mm, and a height of about 15 mm.

Two square notches are provided in the upper edge portion of the lower labyrinth so that the conveyor (chain conveyor) can run. On the other hand, upper and lower labyrinth 21-1,2
Providing rectangular parallelepiped side plates 23 on both sides of 1-2 and on both sides of the upper and lower labyrinths 22-1 and 22-2 to prevent nitrogen gas from flowing out in the lateral direction of the upper and lower labyrinths. , Guides the vertical movement of the upper and lower labyrinths.

It is also possible to increase the resistance of the nitrogen gas flow by forming a labyrinth structure only in the portion corresponding to the distance between the upper labyrinth and the lower labyrinth inside the side plate 23.

41 is attached to the front of the atmosphere furnace body 10,
It is an actuator such as a motor for moving the upper labyrinth 21-1 on the furnace inlet 11 side up and down. 42 is attached to the rear part of the atmosphere furnace main body 10, and the upper labyrinth on the furnace outlet 12 side.
22-1 is an actuator such as a motor that moves up and down.

Lower labyrinth on the furnace inlet 11 side shown in FIG.
21-2 and the lower labyrinth 22-2 on the furnace outlet 12 side are both fixed at predetermined positions. However, in the case of printed wiring board 1 mounted on both sides, this lower labyrinth 21-
2, 22-2 must be moved up and down by an actuator (not shown).

Numeral 25 indicates information about the mounting height of the highest mounted component of the printed wiring board 1, which is installed in front of the furnace inlet 11, more specifically above the conveyor 5 in front of the upper labyrinth 21-1, and detects, for example, the light. It is a sensor such as a sensor or a bar code reader.

Reference numeral 26 is a sensor such as an optical sensor, a micro switch or the like which is installed in the atmosphere furnace main body 10 and detects when the printed wiring board 1 approaches the furnace outlet 12. A control unit 30 controls the actuators 41 and 42, and includes a transfer sequence storage circuit 35 for the printed wiring board 1 in the atmosphere furnace body 10.

To perform reflow soldering by using the reflow device configured as described above, first, cream-like solder is printed and applied on the pad, and the lead or electrode of the mounted component is aligned on the pad. The mounted components are placed on the printed wiring board 1.

The printed wiring board 1 on which the mounting parts are thus temporarily mounted is placed on the conveyor 5 and carried into the atmosphere furnace body 10. Then, when the printed wiring board 1 approaches the furnace entrance 11, the sensor 25 detects information regarding the mounting height of the mounted component.

When the control unit 30 obtains this detection information, the control unit 30 issues an instruction to drive the actuator 41,
The upper labyrinth 21-1 on the furnace inlet 11 side is raised or lowered to a position corresponding to the mounting height of the highest mounted component 2B, that is, a height at which the printed wiring board 1 can pass.

Therefore, the printed wiring board 1 is carried into the atmosphere furnace body 10 through the furnace inlet 11 between the upper and lower labyrinths 21-1 and 21-2 having such a narrow vertical distance. Further, when the sensor 26 installed in the furnace detects that the printed wiring board 1 for which the reflow soldering is completed approaches the furnace outlet 12 and transmits it to the control unit 30, the control unit 30 detects that the printed wiring board 1 The mounting height of the highest mounted component 2B is determined by the transfer order storage circuit 35
Recognized, the actuator 42 is driven, and the highest mounted component
The upper labyrinth on the furnace outlet 12 side is located at a position corresponding to the mounting height of 2B, that is, at a height at which the printed wiring board 1 can pass.
Raise or lower 21-2.

The printed wiring board 1 is carried out of the atmosphere furnace main body 10 through the furnace outlet 12 and the upper and lower labyrinths 22-1 and 22-2 having a small vertical gap. During setup of the reflow equipment and when soldering is not performed, the upper labyrinth 21-1,2
Lower 2-1 to the lowest position and lower labyrinth 21-2,22-2
The furnace inlet 11 and the furnace outlet 12 so that there is no gap between
Is to be closed.

The labyrinth, which has a large resistance to the flow of nitrogen gas, is moved up and down as described above, and the vertical interval is made as narrow as the printed wiring board 1 can pass through. Is suppressed and the running cost is reduced.

In FIG. 4, reference numeral 60 is an optical sensor installed on the furnace inlet 11 side for detecting the mounting height of the highest mounted component mounted on the printed wiring board 1. The optical sensor 60 includes a light emitting element array board 60-1 in which light emitting elements are arranged in a row at a predetermined pitch in the vertical direction, and a light receiving element for receiving emitted light of the light emitting element is arranged in a row at a predetermined pitch in the vertical direction. Light receiving element array board 60
It consists of -2 and.

Such a light emitting element array board 60-1 and a light receiving element array board 60-2 are installed so as to face each other with the conveyor 5 interposed therebetween. Light-emitting element array board 60-1 and light-receiving element array board that are arranged facing each other
When the printed wiring board 1 passes between 60-2 and 60-2, the mounted component blocks the light emitted from the light emitting element, so that no light is incident on the light receiving element corresponding to the light emitting element.

Therefore, the height of the light receiving element at the highest position where no light is received becomes the mounting height of the highest mounted component. Therefore, the control unit 30 obtains the information and recognizes the mounting height of the highest mounted component mounted on the printed wiring board 1. The control unit 30 drives the actuator to move the upper labyrinth 21-1 up and down to a height corresponding to the mounting height of the highest mounted component of the printed wiring board 1.

The method of raising and lowering the labyrinth shown in FIG. 4 will be described in detail below. The actuator that moves up and down the upper labyrinth 21-1 is the motor 50. A thread is threaded on the shaft 51 of the motor 50, and the motor 50 is fixed to the front wall or the like of the atmospheric furnace body 10 so that the shaft 51 is vertically downward.

The lower end of the shaft 51 is rotatably held by a bearing 52. On the other hand, the left and right side edges of the upper labyrinth 21-1 are each provided with a projecting portion, and a screw hole that vertically penetrates one of the projecting portions is provided, and the shaft 51 is screwed into this screw hole. Guide bar on the other protrusion
There is a hole through which 55 passes.

The guide bar 55 is parallel to the shaft 51, and its upper end and lower end are fixed. 53
Is an encoder that detects the rotation angle of the shaft 51 of the motor 50.

54-1 is the lowest position of the upper labyrinth 21-1 (equal to the position of the mounting surface of the printed wiring board 1, the control unit
The origin position detection sensor such as an optical sensor fixed to the front wall or the like of the atmosphere furnace body 10 in order to set (30 circuit configuration becomes simple).

Reference numeral 54-2 is a protrusion for origin fixed to the side surface of the upper labyrinth 21-1 (the side surface of the protruding portion in the figure). Now, when the motor 50 is rotated by a command from the control unit 30, the shaft 51
Rotates. Since the upper labyrinth 21-1 is screwed onto the shaft 51, the upper labyrinth 21-1 starts to descend. The origin protrusion 54-2 descends as the upper labyrinth 21-1 descends,
When the upper labyrinth 21-1 reaches the lowest position, the upper labyrinth 21-1 is fitted into the U-shape of the origin position detection sensor 54-1.

The origin protrusion 54-2 is the origin position detection sensor 54-1.
The origin position detection sensor 54-1 detects this (for example, since the light emitted from the light emitting element of the origin position detection sensor 54-1 is blocked by the origin protrusion 54-2, the origin position detection sensor 54-1 The light receiving element of -1 detects that the origin projection 54-2 has reached the position of the origin position detection sensor 54-1.), That information, that is, the upper labyrinth 21-1 coincides with the origin of the ascending / descending position. Information is transmitted to the control unit 30, and the control unit 30
To stop the rotation of.

In this state, when the printed wiring board 1 is conveyed by the conveyor 5 and reaches the position of the optical sensor 60,
The optical sensor 60 detects the mounting height of the highest mounted component, and the control unit 30
Based on this information, rotates the motor 50 to raise the upper labyrinth 21-1.

Then, the rotation angle of the shaft 51 is detected by the encoder 53, and the moving distance of the upper labyrinth 21-1 from the rotation angle of the shaft 51 (the rotation angle of the motor 50 and the upper labyrinth from the pitch of the thread threaded on the shaft 51). The moving distance of 21-1 can be calculated), and the motor 50 is stopped when the upper labyrinth 21-1 rises to a position slightly higher than the mounting height of the highest mounted component.

Since the reflow device shown in FIG. 5 is applied to both a double-sided mounting printed wiring board and a single-sided mounting printed wiring board, the actuator 41 that moves up and down the upper labyrinth 21-1 on the furnace inlet 11 side, The actuator 43 that moves up and down the labyrinth 21-2, and the upper labyrinth 22 on the furnace outlet 12 side
An actuator 42 for raising and lowering -1 and an actuator 44 for raising and lowering the lower labyrinth 22-2 are provided.

The sensor on the furnace inlet 11 side is replaced with the bar code reader 65. 70 is a printed wiring board 1
It is a bar code displaying the model number of. The barcode 70 is attached along the side edge of the mounting surface of the printed wiring board 1.

On the other hand, the control unit 30 is mounted on the printed wiring boards of all model numbers (the printed wiring boards include one-sided mounting type and double-sided mounting type). It has a memory 31 in which is recorded.

Table 1 shows an example of the memory 31.

[0064]

[Table 1] As shown in Table 1, double-sided mounting printed wiring board 1B (model P0
21 to P024), the mounting heights of the mounted components mounted on the front surface and the rear surface are different. Therefore, in the memory 31, the mounting height dimension of the highest mounted component mounted on the front surface is indicated in the column of the mounting height corresponding to the model number. Record and record the mounting height dimension of the highest mounted component mounted on the back surface in the column on the back side of the mounting height.

In the printed wiring board 1A (model number P010 to P013) mounted on one side, the column on the back side of the mounting height is 0 mm. Since the printed wiring board 1 is conveyed by the conveyor 5 and reaches the position of the barcode reader 65, the barcode reader 65 reads the barcode 70 and reads the model number of the printed wiring board. Control unit
Propagate to 30.

The control unit 30 scans the memory 31 to check the mounting heights of the highest mounted components on both the front and back surfaces of the printed wiring board of that model number, and drives the actuators 41 and 43 to drive the upper labyrinth 21-1 and the lower labyrinth. Raise and lower the labyrinth 21-2 to their respective predetermined positions.

At this time, in the case of the single-sided printed wiring board 1A, the lower labyrinth 21-2 is at the highest predetermined position. When the printed wiring board approaches the furnace outlet 12, the sensor
26 detects this, and the actuator 42 is driven by the command of the control unit 30 to move the upper labyrinth 22-1 up and down to a predetermined position. Further, the actuator 44 is driven to move the lower labyrinth 22-2 up and down to a predetermined position.

Although the above example raises and lowers the labyrinth in accordance with the mounting height dimension of the highest mounted component, the same effect can be obtained in the following manner. That is, the control unit
As shown in Table 1, 30 indicates the mounting height of the highest mounted component mounted on the printed wiring board of that model number at multiple levels.
For example, it is assumed to have a memory in which four levels L ₀ , L ₁ , L ₂ , and L ₃ are classified and recorded.

Then, based on the level read from the memory, the upper and lower labyrinths 21-1, 21-2, 22-1, 22-2 are moved up and down in a predetermined manner. In FIG. 6, reference numeral 75 denotes a box-shaped magazine that accommodates printed wiring boards in multiple stages and has front and rear openings.

71 is a magazine number (for example, M11, M1
2, ..., etc.), and the barcode 71 is attached to the upper plate of the magazine 75. The magazine 75 with the same magazine number contains printed wiring boards 1A, 1
The numbers of B, ..., The number of sheets, and the order in which they are to be accommodated are predetermined and accommodated.

Such a magazine 75 is set at the starting end of the conveyor 5 of the reflow device, and is sequentially discharged to the conveyor 5 from the printed wiring board housed above. Then, a bar code reader for reading the bar code 71 is installed at the position where the magazine 75 is set and is connected to the control unit.

On the other hand, the control unit 30 records the model numbers and the order of accommodation of the printed wiring boards 1 accommodated in all magazines,
In addition, the mounting height of the highest mounted component is classified into a plurality of levels and recorded, for example, a memory as shown in Table 2 is provided.

[0073]

[Table 2] Based on the information from the sensor, the control unit 30 follows the levels read from the memory as shown in Table 2, and the upper and lower labyrinths.
21-1, 21-2, 22-1, 22-2 are moved up and down in a predetermined manner to pass through the printed wiring board.

In the reflow device shown in FIG. 7, the actuator comprises a fluid cylinder 80 and a solenoid valve 81 for switching the moving direction of the rod of the fluid cylinder 80 between forward and reverse directions.

The lower part of the rod of the fluid cylinder 80 is fixed to the central part of the upper surface of the upper labyrinth. Therefore, when the fluid cylinder 80 operates, the upper labyrinth 21-1 moves up or down.

On the other hand, on the side surfaces of the upper labyrinth 21-1 on the furnace inlet 11 side and the furnace outlet 12 side (the upper labyrinth on the furnace outlet 12 side is not shown), there are provided protrusions having flat upper and lower surfaces. Then, on the opposing atmosphere furnace body 10 side corresponding to the protruding portion, an upper stopper 86 with which the upper surface of the protruding portion abuts is provided to define the rising position of the upper labyrinth 21-1, and the lower surface of the protruding portion abuts. A lower stopper 85 is provided to define the lowering position of the upper labyrinth 21-1.

On the other hand, the control unit 30 has a memory as shown in Table 3 in which the mounting heights of the highest mounted components to be mounted on the printed wiring boards of all model numbers are classified into _two levels L ₁ and L ₂ .

[0078]

[Table 3] Then, when the bar code reader 65 reads the bar code 70 attached to the printed wiring board 1, the control unit 30 obtains the information, and according to the level read from the memory shown in Table 3, the upper and lower labyrinths. 21-1, 21-2, 22-1, 22-2 are moved up and down in a predetermined manner to pass the printed wiring board 1.

In FIG. 7, the bar code reader 65 reads the bar code 70 indicating the model number of the printed wiring board, but the bar code reader 65 indicates the bar code 71 indicating the magazine number attached to the magazine. May be read.

As described above, the actuator using the fluid cylinder (for example, air cylinder) has the advantages that the structure is simpler and the cost is lower than that of the motor.

[0081]

As described above, according to the present invention, the labyrinth having a large resistance to the flow of the inert gas (nitrogen gas) is provided at the furnace inlet and the furnace outlet of the atmosphere furnace body so as to be vertically movable, and the printed wiring board is provided. Corresponding to the mounting height of the highest mounted component, the labyrinth vertical spacing is narrow enough to allow the printed wiring board to pass, and the outflow of inert gas (nitrogen gas) can be suppressed and reflow This has the effect of reducing the running cost of the device.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a reflow apparatus according to the present invention.

FIG. 2 is a front view of the reflow device of the present invention.

FIG. 3 is a perspective view showing an example of a labyrinth.

FIG. 4 is a perspective view of a main part of an embodiment of the invention of claim 2;

FIG. 5 is a block diagram of the invention of claim 3;

FIG. 6 is a perspective view of a magazine according to the present invention.

FIG. 7 is a perspective view of an essential part of the invention of claim 6;

FIG. 8 is a sectional view of a conventional example.

FIG. 9 is a front view of a conventional example.

[Explanation of symbols]

1,1A, 1B Printed wiring board 2A, 2B
Mounted parts 5 Conveyor 8 Nitrogen gas supply pipe 10 Atmosphere furnace body 11 Furnace inlet 12 Furnace outlet 15 Square cylinder 21-1,22-1 Upper labyrinth 21-2,22-
2 Lower labyrinth 23 Side plate 25,26
Sensor 30 Control unit 31 Memory 35 Transfer order storage circuit 41, 42, 4
3,44 Actuator 50 Motor 53 Encoder 54-1 Home position detection sensor 54-2
Origin protrusion 55 Guide bar 60 Optical sensor 60-1 Light emitting element array board 60-2 Light receiving element array board 65 Bar code reader 70,71
Bar code 75 Magazine 80 Fluid cylinder 81 Solenoid valve 85 Lower stopper 86 Upper stopper

Claims (6)

[Claims] 1. A printed wiring board is conveyed by a horizontally running conveyor in an atmosphere furnace body filled with an inert gas and kept at a predetermined temperature, and a component mounted on the printed wiring board is reflow-soldered. In the reflow device to be attached, on the front side of the furnace inlet of the atmosphere furnace body, a pair of upper and lower labyrinths mounted so as to face each other with the conveyor in between, and on the rear surface side of the furnace outlet of the atmosphere furnace body, A pair of upper and lower labyrinths mounted so as to face each other with the conveyor interposed therebetween, an actuator for moving up and down at least the upper labyrinth on the furnace inlet side and the furnace outlet side, and a printed wiring board in the atmosphere furnace body. And a control unit for controlling the actuator, which is installed in front of the furnace entrance, and provides information regarding the mounting height of the mounted components of the printed wiring board. The control unit includes one sensor that emits light and another sensor that is installed in the atmosphere furnace main body and that detects that the printed wiring board approaches the furnace outlet. Based on the information, the upper and lower labyrinths on the furnace inlet side are moved up and down to a position corresponding to the mounting height of the mounted component, and based on the detection information of the other sensor, the upper and lower labyrinths on the furnace outlet side. A reflow apparatus for raising and lowering a lower labyrinth to a position corresponding to a mounting height of the mounted component. 2. The reflow apparatus according to claim 1, wherein the sensor installed on the furnace inlet side is an optical sensor for detecting the mounting height of the highest mounted component mounted on the printed wiring board. 3. A bar code indicating the model number of the printed wiring board is affixed to the printed wiring board, and a sensor installed at the furnace inlet side is a bar code reader that reads the bar code, and the control unit is , Having a memory in which the mounting heights of the highest mounted components to be mounted on the printed wiring boards of all model numbers are recorded, and raising and lowering the upper and lower labyrinths based on the information read from the memory. The reflow apparatus according to claim 1, characterized in that. 4. The control unit has a memory in which the mounting heights of the highest mounted components to be mounted on all printed wiring boards are classified into a plurality of levels and recorded, and based on the levels read from the memory, The reflow device according to claim 3, wherein the lower labyrinth is vertically moved. 5. The bar code displaying the magazine number is
The sensor, which is attached to a magazine that houses multiple printed wiring boards, is a bar code reader that reads the bar code and is installed at the furnace entrance side. The control unit stores the magazines in all magazine numbers. It has a memory in which the model number of the printed wiring board and the housing order are recorded, and the mounting height of the highest mounted component is classified into a plurality of levels, and the upper and lower labyrinths are determined based on the levels read from the memory. The reflow apparatus according to claim 1, wherein the reflow apparatus is moved up and down in a predetermined manner. 6. The actuator is a fluid cylinder that moves the upper and lower labyrinths up and down to two high and low positions. And having a memory recorded by classifying into two levels, and moving the upper and lower labyrinths to either a high or low position based on the level read from the memory. The reflow apparatus according to claim 4 or 5, which is characterized in that: