JPH0242296B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a reflow soldering apparatus for soldering leads of an integrated circuit or the like to connection parts of a printed circuit board or the like to which solder is applied in advance.

(Technical Background of the Invention) Conventionally, solder connection parts of printed circuit boards, etc. are plated with solder or paste solder is applied in advance, and leads of integrated circuits, etc. are pressed onto the connection parts and soldered by heating. There is a reflow soldering equipment. Such a device uses a thermocouple to detect the temperature of an instantaneous heating type heater, feeds back a voltage corresponding to the heater temperature, and automatically maintains the heater temperature constant during reflow soldering. Some are equipped with temperature control means. In this case, the heater is pressed against the leads of the integrated circuit to heat the solder joints, and then the current is turned off and the leads are kept pressed by the heater until the molten solder solidifies. Solder the connection parts of printed circuit boards, etc. while preventing them from lifting up.

In such devices, some kind of abnormality occurs in the feedback circuit for controlling the temperature of the heater, such as when the heater is at the end of its lifespan, when the thermocouple is about to come off the heater, or when there is a poor contact in the return path of the thermocouple. If this occurs, the voltage fed back from the heater may not reach the voltage value corresponding to the set temperature, and the heating current continues to flow, which may cause the temperature of the heater to rise abnormally. Such an abnormal rise in heater temperature may cause problems such as destroying the integrated circuit element or scorching the base material of the printed circuit board, causing the conductor to rise from the base material and requiring replacement of the printed circuit board.

(Objective of the Invention) The present invention has been made in view of the above circumstances, and is intended to reliably prevent the temperature of the heater from running out of control when the temperature control of the heater that heats the solder connection part becomes incomplete. To provide a temperature runaway prevention device for a reflow soldering device that prevents the heater temperature from rising too high when the heater heating time is set too long and does not cause thermal damage to integrated circuits or printed circuit boards. The purpose is to

(Structure of the Invention) According to the present invention, the object is to provide a heater that heats a solder joint, a temperature detection means for the heater, a temperature setting means for setting a heater set temperature, and a temperature control means, and a start signal. In a reflow soldering apparatus that performs soldering while maintaining the heater temperature at the heater set temperature, the temperature control means includes a first timer that starts integrating a first set time based on the start signal; a time setting device that makes the first set time variable; and a time setter that detects that the heater temperature reaches the heater set temperature within the first set time and outputs an appropriate temperature signal, and detects that the heater temperature does not reach the set temperature and outputs a stop signal. a second timer that starts integration based on the appropriate temperature signal and outputs a stop signal to the temperature control means to stop heating the heater when a second set time elapses; and an indicator for displaying the supply of heater current from
A reflow soldering apparatus characterized in that when repeating a soldering operation by gradually shortening the setting time, the first setting time can be set slightly longer than the time when the display time of the indicator starts to suddenly shorten. This is achieved by the temperature runaway prevention device.

(Function) The heating time of the heater is divided into the time from the start of heating based on the start signal until the heater reaches the set temperature (referred to as rise time), and the time from the time it reaches the set temperature until it stops heating (second rise time). If the rise time is within the first setting time of the first timer, an appropriate temperature signal is output and the temperature shifts to heat time, and the temperature is normal. Soldering is performed. If the rise time does not fall within the first set time, a stop signal is output.

If the first set time is too long, it is impossible to prevent the temperature of the heater from running out of control. That is, it is desirable to set the first set time to be slightly longer than the time required for the heater to reach the set temperature during normal operation.

The indicator lights up in response to the start signal and continues to light up until the stop signal is output, so if you repeat the soldering operation multiple times while gradually setting the first set time short enough, the indicator will suddenly turn on from a certain set time. The indicator display time becomes shorter. At this time, it means that the heater cannot reach the set temperature within the first set time and a stop signal is output. Therefore, by setting the first setting time slightly longer than this time while looking at the indicator display, the first setting time can be set to an optimal time.

(Example) FIG. 1 is a block diagram showing one embodiment of the present invention.
FIG. 2 is a timing chart of its operation.

In FIG. 1, reference numeral 1 denotes an electric heater, which is made of molybdenum or other heat-resistant material that does not easily wet with solder.

Reference numeral 2 denotes an AC power supply, and 3 a transformer. The AC output of the power supply 2 is supplied to the primary side of the transformer 3 via a triax 4. The secondary side of the transformer 3 is connected to the heater 1. The triax 4 controls the phase of the primary current of the transformer 3 using a gate signal g output from a phase control circuit 11 described later.

A temperature control means 5 controls the phase of the gate signal g so as to maintain the temperature of the heater 1 constant. A thermocouple 6 is attached to the heater 1 as a heater temperature detection means.
The output voltage of is amplified by an amplifier 7. The output voltage of this amplifier 7 indicates the heater temperature t. Reference numeral 8 denotes a temperature setting device, which is composed of a variable resistor that sets an appropriate heater temperature t ₀ depending on the type of solder. 9
is a differential amplifier, into which the output of the amplifier 7 and the output of the temperature setting device 8 are input, and the difference voltage between them is determined. This voltage difference is between the heater temperature t and the set temperature t ₀
It shows the difference (t ₀ −t).

10 is a synchronization signal generation circuit, which outputs a synchronization signal CL in synchronization with the alternating current of the AC power supply 2. Reference numeral 11 denotes a phase control circuit, which outputs a gate signal g at a phase corresponding to the difference (t ₀ -t) in synchronization with this synchronization signal CL.

Reference numeral 12 denotes a start switch, which outputs a start signal a shown in FIG. 2 when turned on. 13
is a first timer made of a monostable multivibrator or the like, and the first set time T1 set by this timer ₁₃ is made variable by a time setter 13a made of a variable resistor. This first timer 13 starts integrating time based on the start signal a, and the output signal b at its Q output terminal is outputted from the first timer 13 as shown in FIG.
It remains at H level for only the set time _T1 , and the output terminal becomes the inverted signal c.

A is a heating detection means, and the first set time T ₁
If the set temperature _t0 has been reached within the set temperature, the appropriate temperature signal d is output, and if it has not been reached, the stop signal j (L level) is output.
This outputs the following. The heating detection means A is composed of a comparator 14, an AND gate 15, an RS flip-flop 16, a NAND gate 18, and the like.

The comparator 14 compares the heater 1 temperature t and the set temperature t ₀
When t> _t0 , an H level suitable temperature signal d is output. 15 is an AND gate to which the signals b and d are input.

16 is an RS flip-flop, and the output e of the AND gate 15 is input to its S input terminal.
The second timer 17 starts integrating time by the output signal f of the RS flip-flop 16, and the second timer 17 transmits the signal h, which changes to H level after the second set time (heat time) _T2 , to the flip-flop 16. Output to the R input terminal of. The output signal i of this flip-flop 16 and the signal c are
It is input to the NAND gate 18. The output signal of this NAND gate 18, that is, the stop signal j, is input to the phase control circuit 11, which allows the circuit 11 to operate when the signal j is at the H level, and prohibits its operation when the signal j is at the L level.

Reference numeral 19 denotes an indicator consisting of a light emitting diode, which lights up when the stop signal j is at the H level (at this time, the heater current I is flowing). That is, it is turned on by the start signal a, and goes out when the stop signal j reaches the level.

Next, the operation of this embodiment will be explained. It is now assumed that the first set time T ₁ of the first timer 13 is set longer than the time (rise time) required for heating the heater 1 to the set temperature t ₀ .

In addition, the temperature setting device 8 is made of, for example, 60% tin and 40% lead.
When using this solder, its melting point is 183 degrees C, so the set temperature _t0 is set at about 300 to 350 degrees C.

When the power is turned on at this time, the first timer 13 and flip-flop 16 are initialized, and the signals Hc and i both become H level. Therefore, the stop signal j becomes L level and prohibits the operation of the phase control circuit 11. Further, at this time, the indicator 19 is not lit.

When the start signal a is input by the start switch 12, the first timer 13 starts integrating.
The signal b becomes H level and the signal c becomes L level. At this time, since the heater temperature t has not yet reached the set temperature _t0 , the signal e remains at the L level, so the signal f of the flip-flop 16 remains at the L level, and the signal i remains at the H level. Therefore, the stop signal j becomes H level, and the phase control circuit 11 starts operating and outputs the gate signal g to the triac 4. Therefore, current I flows through heater 1, and heater temperature t increases. Further, the indicator 19 lights up due to this H level stop signal j.

The heater temperature t reaches the set temperature t ₀ within the first set time T ₁
When it reaches , the output signal d of the comparator 14 changes to H level. Therefore, the output signal e of the AND gate 15 also becomes H level, and the flip-flop 16 is set. In other words, the signal f goes to H level, and the signal i goes to H level.
becomes L level. At this time, the two inputs of the NAND gate 18 both go to the L level, so the output signal j remains at the H level and the heater current continues to flow.
However, in this case, the differential amplifier 9 of the temperature control circuit 5
Since the phase of the thyristor 4 is controlled so that the conduction rate is based on the output (t ₀ −t), the heater current I
is limited and the heater temperature t is maintained at the set temperature t ₀ .

The second timer 17 starts integration based on the signal f, and sets the signal h to the H level when the second set time _T2 has elapsed. Flip-flop 16 is therefore reset. Therefore, the signal i becomes H level, and the signal c of the first timer 13 has already become H level due to the elapse of the first set time _T1 . Therefore, the stop signal j, which is the output of the NAND gate 18, goes to the L level, the heater heating is stopped, and the indicator 19 is turned off.

The above describes the normal operation when the first set time T ₁ of the first timer 13 is properly set. However, if there is a temperature runaway in the heater 1, it is desirable to set the first set time _T1 as short as possible. Because this time
This is because the longer T ₁ , the higher the temperature the heater reaches. Therefore, the procedure for setting this time _T1 using the indicator 19 will be explained.

Now, the first set time _T1 is set to be long enough using the time setter 13a of the first timer 13, and the first set time _T1 is gradually shortened while operating the device several times. Then, a first set time T ₁ occurs in which the lighting time of the indicator 19 suddenly becomes shorter. This is because the first set time T ₁ elapses before the heater temperature t reaches the set temperature t ₀ and the appropriate temperature signal e from the AND gate 15 is not output. That is, since the first set time _T1 of the first timer 13 elapses without the flip-flop 16 being set by the signal e, both the signal c and the signal i are at the H level, and the output of the NAND gate 18 is not set. This is because the signal j becomes L level. The first set time T ₁ at this time is approximately equal to the time required for the heater 1 to reach the set temperature t ₀ , that is, the rise time. Therefore, the time setter 13a of the first timer 13 may be readjusted to set the first set time _T1 to be slightly longer than this rise time.

With the first timer 13 set in this way, if some abnormality occurs in the heater temperature feedback circuit, such as when the thermocouple 6 comes off the heater 1 while using this device, the first timer 13 Even after the set time T ₁ has elapsed, the heater temperature t indicated by the thermocouple 6 does not reach the set temperature t ₀ . Therefore, the output signal d of the comparator 14 does not go to H level, and therefore the flip-flop 16
is not set, and the heater current is cut off after the first set time _T1 has elapsed. That is, the heater temperature t is limited to _t1 , as shown by the imaginary line in FIG.

(Effects of the Invention) As described above, the present invention allows the first set time set by the first timer to be varied by the temperature setting device, and outputs a stop signal when the set temperature is not reached within the first set time. On the other hand, since we have provided an indicator that displays the period from the start signal to the stop signal when the heater current is cut off, when the first set time is gradually shortened and the soldering operation is repeated, the display time of the indicator suddenly becomes shorter. Therefore, the rise time required for the heater temperature to reach the set temperature can be detected, and by setting the first set time slightly longer than this time, the first set time can be set sufficiently short within the necessary range. . Therefore, temperature runaway of the heater can be reliably prevented, and thermal damage to the integrated circuit or printed circuit board can be prevented.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of a temperature runaway prevention device for a reflow soldering apparatus according to the present invention, and FIG. 2 is an operation timing chart thereof. 1... Heater, 5... Temperature control means, 6... Thermocouple as temperature detection means, 8... Temperature setting device,
13...First timer, 13a...Time setting circuit, 14...Comparator, A...Heating detection means, 17
...Second timer, 19...Indicator, T ₁
...First set time, T ₂ ...Second set time, t...
...Heater temperature, _t0 ...Set temperature, a...Start signal, d...Appropriate temperature signal, j...Stop signal.

Claims (1)

[Scope of Claims] 1. A heater that heats a solder joint, a temperature detection means for the heater, a temperature setting means for setting a set temperature of the heater, and a temperature control means, the temperature control means being controlled based on a start signal. is a reflow soldering apparatus that performs soldering while maintaining the heater temperature at the heater set temperature, comprising: a first timer that starts accumulating a first set time based on the start signal; and a variable first set time. a time setting device; a heating detection means for detecting that the heater temperature has reached the heater set temperature within the first set time and outputting an appropriate temperature signal; and detecting that the heater temperature has not reached the set temperature and outputting a stop signal; a second timer that starts integration based on the appropriate temperature signal and outputs a stop signal to the temperature control means to stop heating the heater when a second set time has elapsed; an indicator that displays current supply; when repeating the soldering operation by gradually shortening the first set time using the time setting device,
A temperature runaway prevention device for a reflow soldering apparatus, characterized in that the first set time can be set slightly longer than the time when the display time of the indicator starts to suddenly shorten.