JPH0410864B2 - - Google Patents

Description

[Detailed Description of the Invention] [Summary] In a magnet drive device having a drive coil, a constant current drive circuit that supplies a constant current to the drive coil is used to perform a normal printing operation, and also for testing purposes. It is equipped with a constant voltage application circuit that applies a constant voltage to the drive coil, and a temperature monitoring circuit that detects the current flowing by applying the constant voltage to the drive coil and monitors the temperature. , to prevent abnormal heating of the drive coil.

[Industrial application field]

The present invention relates to a magnet drive device configured to apply a constant voltage to a drive coil that operates a magnet by constant current drive and to monitor temperature rise during a test.

[Conventional technology]

Conventionally, the temperature rise of the drive coil that drives the printing pins of wire dot printers has been monitored by connecting a constant voltage source to the drive coil and detecting the voltage change across the drive coil as the coil resistance increases due to temperature rise. I was walking over.

[Problem that the invention seeks to solve]

On the other hand, conventionally, a method has been adopted in which a constant current is supplied to the drive coil during normal printing operations. If you try to do this, you will have to prepare power sources for both a high-precision constant voltage source to monitor the temperature rise of the drive coil and a high-precision constant current source to drive the drive coil with constant current. The dot was hot.

[Means for solving problems]

In order to solve the above-mentioned problems, the present invention provides a configuration in which a constant voltage can be collectively applied to a plurality of drive coils from the same power source during temperature monitoring to the drive coils that are driven with a constant current. By adopting this method, the temperature rise of the drive coil can be monitored using a simple circuit.

Means for solving the problems will be explained using the configuration of one embodiment of the present invention shown in FIG.

In FIG. 1, a constant current drive circuit 1 connects one of drive coils _L1 to Ln in response to the input of an excitation signal.
For example, a predetermined constant current is supplied to each of them, for example, _L1 . As a result, a predetermined pin of, for example, a wire dot printer is driven to perform printing.

The constant voltage application circuit 2 used during the test applies a predetermined constant voltage to the drive coils _L1 to Ln.

The temperature monitoring circuit 3 detects the voltage generated in the resistor R ₁ when a constant voltage is applied to the drive coils L ₁ to Ln by the constant voltage application circuit 2, and monitors the temperature rise of the drive coils L ₁ to Ln. It is to monitor.

[Effect]

In the configuration explained using FIG. 1, during normal printing, the constant current drive circuit 1 is used to control whether or not constant current is applied to each drive coil, but during testing, the test signal shown in the figure is used to control whether or not to apply constant current to each drive coil. By inputting the voltage, a constant voltage determined by the Zener diode ZD ₁ is applied to the base of the transistor Tr ₁ . Therefore, a predetermined constant voltage is applied to the drive coils _L1 to Ln connected to the emitter of the transistor _Tr1 . Then, a voltage corresponding to the current flowing at this time is generated across the resistor _R1 . By inputting this generated voltage to the temperature monitoring circuit 3, it is determined whether the temperature of the drive coil has risen above a predetermined threshold temperature. For example, if it is determined that the temperature has risen above a predetermined threshold, the duty of the excitation signal is reduced, that is, the printing speed is slowed down, and the amount of heat generated by the drive coils _L1 to Ln is reduced to reduce the temperature rise. It is controlled to hold it down.

〔Example〕

FIG. 1 shows a configuration diagram of one embodiment of the present invention. In the figure, 1 is a constant current drive circuit provided corresponding to the drive coils L ₁ to Ln, respectively, and 2 is the drive coil L ₁
or a constant voltage application circuit commonly provided for Ln,
3 is a temperature monitoring circuit, _L1 to Ln are drive coils, which are connected to the constant voltage application circuit 2 in sets of 6 coils, for example, and 24 coils in total can be provided in 4 sets of 6 coils, Tr. ₁ , Tr ₂ , Tr ₄ and Tr ₅ are transistors, ZD ₁ is a Zener diode, and R ₁ and R ₂ are resistors.

In FIG. 1, when trying to excite (drive) the drive coil _L1 with a constant current, an H level block selection signal (selecting one or more of the four sets) is applied to the transistor _Tr4 . Enter the base. As a result, the transistors Tr ₄ ,
Tr ₂ and Tr ₁ become conductive, and drive coil L ₁
A power supply voltage V is applied to Ln through Ln. and,
Drive coil L ₁ to be excited with H level excitation signal
By inputting the constant current to the constant current drive circuit 1 corresponding to one of the voltages Ln to Ln, the drive coil _L1 is connected so that a current corresponding to the reference voltage is generated in the resistor _R1 .
A constant current is supplied to either Ln or Ln,
For example, the pins of a wire dot printer are driven.

Next, when attempting to monitor the temperature rise of the drive coils _L1 to Ln, an H level test signal is input to the base of the transistor _Tr5 . This results in
Transistor Tr ₅ becomes conductive, and a predetermined constant voltage is applied to the base of transistor Tr ₁ by resistor R ₂ and Zener diode ZD ₁ . Therefore, a predetermined constant voltage is applied to the drive coils _L1 to Ln connected to the emitter of the transistor _Tr1 . And this drive coil
The current value flowing through L ₁ to Ln is detected by the resistor R ₁ and input to the temperature monitoring circuit 3 . The input voltage is compared with the normal voltage, and the control circuit is notified of the result. For example, if this notification is determined to indicate that the drive coil _L1 to Ln has risen above a predetermined threshold temperature, the duty of the excitation signal is reduced (printing speed is slowed) to reduce the amount of heat generated by the drive coil. control to do so.

As explained above, the drive coils _L1 to Ln
When driving a pin by supplying a constant current to perform printing, the power supply voltage V is directly applied to one end of the drive coil _L1 to Ln, and constant current drive is performed using the constant current drive circuit 1. There is. On the other hand, drive coil L ₁
When monitoring the temperature rise of L1 to Ln, a test signal is input, a constant voltage is applied to the drive coils _L1 to Ln, and the current flowing at this time is detected to monitor the temperature rise. Therefore, temperature monitoring can be performed using a simple configuration.

FIG. 2 shows a block diagram of another embodiment of the present invention.

In FIG. 2, the transistor Tr ₆ applies a constant voltage to the drive coil Li (i is 1 to n),
It is for supplying constant current.

First, when driving the drive coil Li with a constant current to perform printing, etc., a drive signal is input to the constant current drive circuit 1. As a result, the base voltage of the transistor Tr ₇ is controlled so that a current corresponding to a preset reference voltage flows through the resistor R ₁ . For this reason,
A constant current flows from the power supply V ₁ to the ground via the transistor Tr ₆ , the drive coil Li, and the resistor R ₁ .
The drive coil Li is driven by this constant current to perform printing and the like.

Second, when applying a constant voltage to the drive coil Li to monitor the temperature rise, an H-level test signal is input to the base of the transistor Tr ₈ forming the constant voltage application circuit 2 . As a result, a predetermined constant voltage generated by the resistor R ₃ and the Zener diode ZD ₂ is applied to the base of the transistor Tr ₆ . Therefore, a predetermined constant voltage is applied from the power supply _V1 to one end of the drive coil Li via the transistor _Tr6 . Then, a resistance-dependent current corresponding to the temperature rise of the drive coil Li is detected by the resistor R ₁ and input to the temperature monitoring circuit 3. This input voltage is compared with the normal voltage, and a result signal is sent out. For example, if the transmitted result signal is a result signal determined to have risen above a predetermined threshold temperature, the duty of the drive signal is reduced (printing speed control to slow down).

As explained above, the transistor Tr ₆ can be used for both constant current driving and constant voltage application. By adopting this configuration, the configuration can be simplified by using one control output transistor for each drive coil Li.

〔Effect of the invention〕

As explained above, according to the present invention, since a configuration is adopted in which a constant voltage is applied from the same power supply to the drive coil that is driven at a constant current during temperature monitoring, the drive coil can be driven using a simple circuit. The temperature rise of the coil can be monitored with good accuracy.

[Brief explanation of drawings]

FIG. 1 is a block diagram of one embodiment of the present invention, and FIG. 2 is a block diagram of another embodiment of the present invention. In the figure, 1 is a constant current drive circuit, 2 is a constant voltage application circuit, 3 is a temperature monitoring circuit, _L1 to Ln are drive coils, _Tr1 , _Tr2 , _Tr4 , _Tr5 are transistors, _ZD1
represents a Zener diode, and R ₁ and R ₂ represent resistances.

Claims (1)

[Scope of Claims] 1. A plurality of drive coils, a magnet driven by excitation of the drive coils, and a constant current drive circuit 1 that supplies a constant current to each of the drive coils to drive the magnet, In a magnet drive device equipped with, during testing, instead of the control by the constant current drive circuit 1, a constant voltage application circuit 2 applies a constant voltage to the drive coil, and a constant voltage is applied by this constant voltage application circuit 2. A temperature monitoring circuit 3 is provided which detects the current flowing through each of the drive coils by applying it to the drive coil and monitors the temperature, and based on the result of monitoring by the temperature monitoring circuit 3, A magnet drive device characterized in that it is configured to prevent abnormal heating of the drive coil operated by the constant current drive circuit 1.