JPH0356982A - Flashing control method for flash lamp - Google Patents

Abstract

PURPOSE:To prevent danger that voltage might reside in a capacitor by allowing a flash lamp to emit light after charging of the capacitor is continued until a charging completion signal is outputted. CONSTITUTION:After the charging of the capacitor 4 is instructed by a control means 21, it is continued by the continuing means 22 until the charging completion signal is outputted from a charging means 23 even when a charging stop instruction signal is outputted from the control means 21 in response to an abnormality detecting report outputted from an abnormality detecting circuit 8. Then, the charging means 23 allows the flash lamp 24 to emit the light. After the charging is continued until the terminal voltage of the capacitor 4 reaches a stable voltage value that discharging of the flash lamp 24 is possible, a trigger pulse is applied to the flash lamp 24 and the light is emitted, whereby it is eliminated that voltage resides in the capacitor 4.

Description

[Detailed Description of the Invention] [Summary] To prevent danger due to residual voltage for causing a flash lamp to emit light in a device that fuses and fixes a toner image transferred to a print medium using the emission energy of a flash lamp. Regarding the flash lamp emission control method, the purpose is to prevent dangerous voltage from remaining in the capacitor and pose a danger to the human body.When a charging instruction signal is received, the capacitor is charged and charging is stopped. a charging means that stops charging the capacitor when receiving an instruction signal and sends a charging completion signal when the terminal voltage of the capacitor reaches a certain voltage value; In a device equipped with a flash lamp that emit light by consuming the energy stored in the capacitor when it is instructed to emit light later, when the charging stop instruction signal is sent, the terminal voltage of the capacitor changes to the constant voltage. means for continuing charging until the value is reached and a charging completion signal is sent from the charging means, and after the charging instruction for the capacitor is received, until the charging means sends out the charging completion signal; After continuing the charging operation, the flash lamp is set to emit light.

[Industrial application field]

The present invention relates to a device that fuses and fixes a toner image transferred to a print medium using the light emitted energy of a flash lamp.
In particular, the present invention relates to a flash lamp light emission control method that prevents danger caused by residual voltage for causing the flash lamp to emit light.

In printing devices, copying devices, etc. that print using a dry electrophotographic method, toner is attached to a latent image formed on an image bearing member such as a photosensitive drum and developed, and this image i! After transferring the toner image formed on the L carrier onto a printing medium, a flash lamp such as a xenon lamp is emitted, and the toner image transferred onto the printing medium is melted and fixed by the emitted energy. is being carried out.

When fixing a toner image using a flash lamp such as a xenon lamp, generally a capacitor is charged, and after the terminal voltage of the capacitor reaches a predetermined voltage, a trigger signal is given to the xenon lamp. This induces a discharge within the capacitor and converts the energy stored in the capacitor into the energy emitted by the xenon lamp.

By the way, a xenon lamp will not discharge even if a trigger signal is applied unless a high voltage higher than a certain value is applied. Therefore, if charging is stopped while the capacitor is being charged, the xenon lamp will not discharge even if a trigger signal is sent, and a voltage dangerous to the human body may remain in the capacitor. Any residual voltage needs to be removed.

[Conventional technology]

FIG. 4 is a block diagram illustrating an example of the prior art.
The figure is a time chart explaining the operation of FIG. 4.

A control circuit 1 for a printing device, a copying device, etc. that prints using the dry electrophotographic method has a xenon lamp 5 emitted by a fall detection circuit 9 and an AND circuit 12 of a flash control circuit 2, as shown in FIG. 5 CHONP. Logic ゜1'' is sent out as a charging instruction signal to cause the charging.

As shown in FIG. 5 JAMS, the abnormality detection circuit 8 detects NO of the control circuit 1 and the flash control circuit 2 when the device is operating normally.
A logic "0" is sent to the T circuit 13 and the OR circuit 1l, but if the print medium jams, if the motor or drive circuit of the print medium conveyance system malfunctions, or if the operator When an abnormality is detected, such as when the cover of the transport system is opened, a logic "1" is sent out.

Therefore, when the device is in normal operation, the NOT circuit l3 sends a logic code to the AND circuit 12, so the AND circuit l2
is the C output from the control circuit 1, as shown in FIG.
In synchronization with the HONP signal, a logic code is sent to the flash power supply 3 as a signal instructing the capacitor 4 to be charged.

Since the flash t source 3 continues to supply current to the capacitor 4 while the CHRG signal is logic "1", the terminal voltage of the capacitor 4 increases, and the flash power source 3 can send out the voltage as shown in FIG. 5 VC. Charges until the maximum output voltage is reached.

Even after the capacitor 4 has been charged to a predetermined voltage, that is, the maximum output voltage value of the flash power supply 3, the control circuit 1 continues to send out a logic "CHONP" signal until flash tying for the print medium is reached. Then, when it comes to flash timing, this CHONP
The logic "1" of the signal is assumed to be IIQII.

Therefore, the AND circuit l2 converts the CHRG signal to logic "0".
, and the charging operation of the flash power supply 3 is stopped.

The falling detection circuit 9 detects the falling edge of the CHONP signal.
That is, it detects that the logic becomes "0" and instructs the trigger pulse generation circuit 10 to send out a trigger pulse. Therefore, the trigger pulse generating circuit 10 sends out a logic "1" through the OR circuit 11 as a signal instructing the flash power supply 3 to send out a trigger pulse, as shown in FIG. 5 TRG.

When the TRG signal becomes logic '1'', the flash power supply 3
A current is sent to the trigger coil 7, and based on this current, the trigger coil 7 provides the xenon lamp 5 with a high-voltage trigger pulse that enables the internal discharge of the xenon lamp 5 to start.

Therefore, the xenon lamp 5 starts an internal discharge and emits light by discharging the energy stored in the capacitor 4 through the coil 6, and the emitted energy melts the 1.ner on the printing medium.

Therefore, as shown in FIG. 5V, the terminal voltage of the capacitor 4 decreases to zero potential due to the discharge of the xenon lamp 5, and the control circuit 1 again sets the CHONP signal to logic "1", so that It will be charged again.

When the abnormality detection circuit 8 detects the occurrence of a jam in a print medium, for example, it sends a logic "1'" to the control circuit 1, NOT circuit 13', and OR circuit 11, as shown in FIG. 5, JAMS.
Therefore, the NOT circuit 13 outputs the logic "0'" to the AND circuit 1.
2 and converts the CHONP signal sent by the control circuit 1 to logic "0'", the CHRG signal becomes logic "O'".
becomes.

The flash power supply 3 stops charging the capacitor 4 when the CHRG signal becomes logic "O". Therefore, the terminal voltage of the capacitor 4 is as shown in (2) in FIG. 4V. As shown in the figure, charging is stopped when the battery is charged to a low voltage before reaching a predetermined voltage.

On the other hand, the logic "1" of the JAMS signal is sent out through the OR circuit 11, and as shown in FIG.
A logic "1" is sent out as a trigger signal.

Therefore, the flash power supply 3 supplies a current Q to the trigger coil 7, and the trigger coil 7 provides a trigger pulse to the xenon lamp 5.

[Problem to be Solved by the Invention] However, if the terminal voltage VC+ of the capacitor 4 has not reached a certain voltage at which discharging can be started by the trigger pulse of the xenon lamp 5 because the charging of the capacitor 4 is stopped midway, the xenon Since the lamp 5 does not start discharging even when a trigger pulse is applied, the voltage Vel remains in the capacitor 4.

In such a case, the maintenance person can detect the abnormality by the abnormality detection circuit 8. The xenon lamp lighting circuit is inspected, circuit parts are replaced, etc., but if the voltage remaining in the capacitor 4 is relatively high, there is a problem that it poses a danger to the human body.

In view of these problems, it is an object of the present invention to prevent dangerous electrolyte from remaining on the capacitor when stopping the light emitting operation of a flash lamp, thereby posing no danger to the human body.

[Means to solve the problem]

FIG. 1 is a diagram explaining the principle of the present invention.

The control means 21 sends a charge instruction signal instructing the charging stage 23 to charge the capacitor 4 via the continuation means 22, and at a predetermined timing, sends a charge stop instruction signal to instruct the charging stage 23 to emit light. At the same time, based on the abnormality detection report from the abnormality detection circuit 8, a charge stop instruction signal is sent to the capacitor 4.

The charging means 23 charges the capacitor 4 based on the charging instruction signal sent by the control means 21, and also charges the capacitor 4.
When the terminal voltage reaches a predetermined constant voltage value, a charge completion signal is sent to the continuation stage 22.

When the charging means 23 is instructed to emit light by sending out a charging stop instruction signal through the continuation stage 22 in the control stage 21 after the terminal voltage of the capacitor 4 exceeds a certain voltage value, the trigger coil 7 is activated. A trigger pulse is applied to the flash lamp 24 through.

Since the flash lamp 24 is applied with a voltage higher than a certain voltage value, it starts discharging in response to the trigger pulse, consumes the energy stored in the capacitor 4, and emits light.

After the control means 21 instructs the capacitor 4 to be charged, the continuation means 22 causes the charging means 23 to complete charging even if the control means 21 sends out a charging stop instruction signal based on the abnormality detection report sent by the abnormality detection circuit 8. The charging operation for the capacitor 4 continues until the signal is sent out.

Then, the charging means 23 is connected to the flash lamp 24 in the same manner as described above.
to emit light.

[Effect]

As described above, even if the control stage 21 instructs the charging means 23 to stop charging the capacitor 4 due to an abnormality detection report, the continuation stage 22 will cause the terminal voltage of the capacitor 4 to reach the flash lamp level. After charging is continued until a constant voltage value at which the flash lamp 24 can be discharged is reached, a trigger pulse is given to the flash lamp 24 to cause it to emit light, so that no voltage remains in the capacitor 4.

Therefore, the danger of electric shock to maintenance personnel can be prevented.

〔Example〕

FIG. 2 is a block diagram of a circuit showing an embodiment of the present invention.
FIG. 3 is a time chart explaining the operation of FIG. 2.

In FIG. 2, the same symbols as in FIG. 4 indicate the same functions. The control circuit 1 sends a logic "1" to the S terminal of the flimp flop 19 of the flash control circuit 20 and the NOT circuit 15 as a charge instruction signal for causing the xenon lamp 5 to emit light, as shown in FIG. 3 CHONP. Therefore, the flip-flop 19 is set and outputs logic "1" from the Q terminal to the falling detection circuit 9 and the flash voltage 'rJ1.
Send to 4.

As shown in FIG. 3 JAMS, the abnormality detection circuit 8 is connected to the control circuit 1 and the flash control circuit 20 when the device is operating normally.
A logic "O" is sent to the ND circuit 17, but as explained in FIG. 4, when an abnormality is detected, a logic "1" is sent.

When the control circuit 1 sends a CHONP signal of logic "1", the NOT circuit 15 sends a logic "0" to the AND circuit 16. Also, flash electricity? al4 is flip-flop 1
9 starts charging the capacitor 4 when it sends a logic "1", and until the capacitor 4 is charged to a certain voltage value, the logic "0" is sent to the flash control circuit 20 as shown in FIG. 3 CHOK. In order to send the output to the AND circuits 16 and 17, the AND circuits 16 and 17 pass through the OR circuit 18, and the logical
0'' is sent to the R terminal of the flip-flop 19.

Therefore, the flip-flop 19 has a logic "1" in the control circuit l.
It remains set while the CHONP signal of `` is being sent, and the CHRG signal of logic ``1'' is being sent to the flash power supply 14 .

In the flash charge R14, the charging voltage of the capacitor 4 is
When the constant voltage shown at VC2 in FIG.
Send to.

Therefore, the control circuit 1 sends the logic "0" CHONP signal to the flip-flop 19 and N, as shown in FIG.
When sent to the OT circuit 15, the AND circuit 16 outputs logic “1”.
” is sent to the R terminal of the flip-flop 19 through the OR circuit 18°.

In the flip-flop 19, logic “0” is input to the S terminal, and R
Since logic "1" is input to the terminal, it is reset and sends logic "0" from the Q terminal to the flash power supply 14, and the flash power supply 14 stops charging the capacitor 4.

In the falling detection circuit 9, the flip-flop 19 has a logic “
When O' is sent out, the trigger pulse generation circuit IO is instructed to send out a trigger pulse. Therefore, as shown in FIG.
The logic “l” is used as a signal instructing the trigger pulse to be sent to
” is sent.

When the TRG signal becomes logic "1", the flash power supply 14 sends a current to the trigger coil 7, which provides a high voltage trigger pulse to the xenon lamp 5 as described above.

Therefore, the xenon lamp 5 starts an internal discharge and emits light by discharging the energy stored in the capacitor 4 through the coil 6, and the emitted energy melts the toner on the print medium.

Therefore, the terminal voltage of the capacitor 4 drops to zero potential due to the discharge of the xenon lamp 5, as shown in FIG. It will be charged.

For example, when the abnormality detection circuit 8 detects the occurrence of a jam in a print medium, the JAMS signal is set to logic "1" as shown in FIG. 3, JAMS.
The S signal is sent to the control circuit 1 and the AND circuit 17. Therefore, the control circuit 1 has a logic "
A CHONP signal of 0'' is sent to the S terminal of the flimp flop l9 and the NOT circuit l5.

However, the flash power supply 14 connects the logic "O" to the AND circuits 16 and 17 until the capacitor 4 is charged with a constant voltage.
Since the NOT circuit l5 sends the logic “1” to A
Even if the signal is sent to the ND circuit 16, the AND circuit 16 will have a logic “0”.
”, and the AND circuit 17 also sends out a logic “0”, so the OR circuit 18 sends out a logic “0” to the R terminal of the flip-flop 19. Therefore, the flip-flop 19 Not reset.

As shown in FIG. 3 CHOK, when the terminal voltage of the capacitor 4 reaches the constant voltage VC2, the flash voltage #14
A CHOK signal of logic "L" is sent to AND circuits 17 and 16.

Therefore, the AND circuits l6 and l7 send a logic "1" to the R terminal of the flip-flop 19 via the OR circuit 18, so the flip-flop l9 is reset and a logic "O" is sent from the Q terminal to the fall detection circuit 9. and flash electric 'a'
Send on 14th.

Therefore, the flash power supply 14 stops charging the capacitor 4, and the trigger pulse generation circuit 10 outputs a logic "1".
” is sent to the flash power source 14. Here, the flash power source 14 applies a trigger pulse to the xenon lamp 5 via the trigger coil 7, but at this time, a constant voltage value is applied to the xenon lamp 5. Therefore, discharge starts, and the terminal voltage of the capacitor 4 drops to zero potential.

As shown in FIG. 3 JAMS, the abnormality detection circuit 8 continues to send out logic "1" while the abnormal state continues, so the control circuit 1 outputs logic "0" CHONP as shown in FIG. 3 CHONP. Continue sending signals.

Therefore, the capacitor 4 will not be charged again.

〔Effect of the invention〕

As explained above, the present invention is applicable to the capacitor when using a fixing device using a flash lamp that fixes a toner image by converting the energy of the capacitor charged with a high voltage higher than a certain voltage value into luminous energy. Since no dangerous voltage remains, electric shock accidents for maintenance personnel can be prevented.

[Brief explanation of drawings]

FIG. 1 is a block diagram explaining the principle of the present invention, FIG. 2 is a block diagram of a circuit showing an embodiment of the present invention, FIG. 3 is a time chart explaining the operation of FIG. 2, and FIG.
The figure is a block diagram explaining an example of the prior art, and FIG. 5 is a time chart explaining the operation of FIG. 4. In the figure, 1 is a control circuit, 2 and 20 are flash control circuits,
3.14 is a flash power supply, 4 is a capacitor, 5 is a xenon lamp, 6 is a coil, 7 is a trigger coil, 8 is an abnormality detection circuit,
9 is a rising edge detection circuit, 10 is a trigger pulse generation circuit, 11.18 is an OR circuit, 12, 16. 17 is AN
D circuit, 13. 15 is a NOT circuit, 19 is a flip-flop, 2l is a control means, 22 is a continuation means, 23
24 is a charging means, and 24 is a flash lamp. 7 Illnesses and Explanation of Fudatsuro's 7 Illusions/Explanations 1st Diagram CHONI' 2nd Mouth

Claims (1)

[Claims] When a charging instruction signal is received, the capacitor (4) is charged, and when a charging stop instruction signal is received, charging of the capacitor (4) is stopped, and the terminal voltage of the capacitor (4) is kept constant. A charging means (23) that sends out a charging completion signal when a voltage value is reached; and a charging means (23) that sends out a charging completion signal when a voltage value is reached; In a device equipped with a flash lamp (24) that emits light by consuming energy, when the charging stop instruction signal is sent, the terminal voltage of the capacitor (4) reaches the constant voltage value, and the charging stops. Means (22) is provided for continuing charging until a charge completion signal is sent from the means (23), and after the charging instruction signal for the capacitor (4) is received, the charging means (23) continues the charging. The charging operation is continued until a completion signal is sent, and then the flash lamp (24
) A flash lamp light emission control method characterized by causing a flash lamp to emit light.