JP2000289195A - Driving circuit for ink jet head - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce an unevenness of a voltage rise of a piezoelectric element even when number of the elements is changed by connecting a Zenor diode having a Zenor voltage equal to a driving voltage of the element between power supply terminals of a power supply circuit, and raising the voltage of a DC power source to a larger voltage than a driving voltage of the element. SOLUTION: A time difference between a time when a rising voltage V of N pieces of piezoelectric elements at a driving voltage V and a time when a rising voltage V of one element arrives at the voltage V1 is shorter at (tn'-t1') than a time difference (tn-t1). That is, when a voltage Vx of a DC power source 41 is set to a voltage V2 higher than the voltage V1, an uneven time until the voltage V of the element arrives at the voltage V1 is resultantly alleviated. A Zenor diode 51 of a Zenor voltage V is connected between output terminals 40 and 50 of a power supply circuit 32. Thus, even when the voltage Vx of the power source 46 is the voltage V2 larger than the voltage V1 of the element, a voltage exceeding the voltage V1 is not applied to the respective elements, and no fault occurs.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving circuit of an ink jet head for driving a piezoelectric element of the ink jet head.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 11, a plurality of piezoelectric elements 4 to 12 and
2. An ink jet head comprising: a piezoelectric element drive circuit 2 having transistors 13 to 21 connected in series to the piezoelectric element 2; and a power supply drive circuit 3 for supplying power to each of the piezoelectric elements 4 to 12 of the piezoelectric element drive circuit 2. A drive circuit 1 is known. Each of the transistors 13 to 21 of the driving circuit 1 is
The base terminal is connected to a print signal generation circuit (not shown),
The print signal is output from the print signal generating circuit to conduct. When the transistors 13 to 21 conduct, the corresponding piezoelectric elements 4 to 12 are fed by the feed circuit 3. The supplied piezoelectric element causes distortion on the pressure generating chamber side (not shown) of the ink jet head, and the ink is ejected from a nozzle hole (not shown) by a pressing force due to the distortion.

[0003]

In the ink jet head drive circuit 1, the number of piezoelectric elements to be driven at the time of printing differs depending on the shape of the character to be printed.

Here, the capacitance of each of the piezoelectric elements 4 to 12 is C and the internal resistance is R, and among the piezoelectric elements 4 to 12,
When a voltage V ₀ is applied from the power supply circuit 3 to the n devices, the voltage of the piezoelectric element becomes V ₀ × ｛1-exp (−t / nC
R) rises according to the curve of (t: time).

According to this curve, the rising of the voltage of the piezoelectric element varies according to the number n of the piezoelectric elements to be driven, as shown in FIG. That is, as the number of nozzles from which ink is ejected increases, the rise of the voltage is delayed, and the ejection speed of the ink is reduced. That is, the ejection speed of the ink varies depending on the number of nozzles, and as a result, the ejection speed of the ink is not constant, and there is a problem in that the quality of printing deteriorates.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a drive circuit for an ink jet head capable of reducing variations in voltage rise of piezoelectric elements even when the number of driven piezoelectric elements fluctuates. The purpose is to do.

[0007]

According to a first aspect of the present invention, there is provided a piezoelectric device having a plurality of piezoelectric elements connected in parallel and a switching element connected in series to each piezoelectric element. A piezoelectric element driving circuit, and a power supply circuit having a DC power supply for supplying power to the piezoelectric element, and an inkjet head that discharges ink by applying a voltage of the DC power supply to each piezoelectric element by conducting each switching element. A drive circuit, wherein a zener diode having a zener voltage equal to the drive voltage of the piezoelectric element is connected between power supply output terminals of the power supply circuit, and the voltage of the DC power supply is set higher than the drive voltage of the piezoelectric element. Features.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a drive circuit for an ink jet head according to the present invention will be described below with reference to the drawings.

The driving circuit 30 of the ink-jet head includes:
As shown in FIG. 1, a plurality of piezoelectric elements A connected in parallel
₁ , A ₂ ,... A _N−1 , A _N and transistors (switching elements) B ₁ connected in series with the respective piezoelectric elements A _{1 to} A _N.
Piezoelectric element drive circuit 3 having B ₂ ,... B _N-1 , B _N
1 and a power supply circuit 32 for supplying power to the piezoelectric element drive circuit 31.

One end of each of the piezoelectric elements A _{1 to} A _N is connected to the collector terminals of the transistors B _{1 to} B _N. The emitter terminal of the transistor B ₁ .about.B _N is grounded, the base terminal connected to a print signal generating circuit (not shown). Each of the transistors B _{1 to} B _N is turned on when a print signal 1 ^{# to} N ^# output from a print signal generation circuit is input to a base terminal.

As shown in FIG. 2, the power supply circuit 32 includes Schmitt circuits 41 and 42 for removing noise of the pulse signal D output from the pulse signal generation circuit 40, and pulse signals output from the Schmitt circuits 41 and 42. a transistor 43 to conduct by D, in conduction the transistor 43 is conductive, the resistor voltage V ₂ of the DC power supply 47 52
Transistor 44 which is applied to the output terminal 49 via
A transistor 45 which is turned on by a pulse signal D output from the Schmitt circuits 41 and 42, and a transistor 45 which is turned on when the transistor 45 is turned off to connect the output terminal 49 to the resistor 5
And a transistor 46 grounded via the transistors 2 and 53. The output terminal 49 is connected to the cathode of a Zener diode 51, and the grounded output terminal 50 is connected to the anode of the Zener diode 51. here,
Zener diode 51 has an equal zener voltage to the driving voltage V ₁ of the piezoelectric element A ₁ to A _N. Further, the voltage V ₂ of the DC power supply 47 is set larger than the drive voltage V ₁ of the piezoelectric element A ₁ to A _N.

Next, the driving circuit 3 for the ink jet head
The operation of 0 will be described.

[0013] For example, when a print signal 1 ^# is input to the base terminal of the transistor B _1, the transistor B ₁ is conductive. On the other hand, as shown in FIG.
When the pulse signal D is output from the power supply circuit 32, the transistor 43 is turned on and the transistor 44 is turned on.
Only the piezoelectric element A ₁ is powered by the DC power supply 47. Then, when the pulse signal D is turned off, the transistor 4
The transistor 45 is turned off together with the transistor 4, and the transistor 4
Since 6 conducts the piezoelectric element A ₁ is discharged, then, the print signal 1 ^# off. Ink is discharged from the nozzle holes corresponding to the piezoelectric element A ₁ in the same manner as conventional by feeding to the piezoelectric element A _1. Similarly, when the other print signal 2 ^# to N ^# is input to the base terminal of the transistor B ₁ .about.B _N, the printing by discharging the ink from the nozzle holes corresponding to the piezoelectric elements A ₁ to A _N are performed .

Here, each piezoelectric element A₁~ A_NAnd the power supply circuit
32 V DC power supply 47 _XWhen power is supplied by
The rising voltage V of the piezoelectric element is V = V_X× ｛1-ex
p (−t / nCR)}. Where t is hour
C, each piezoelectric element A₁~ A_NAnd R is a resistance of 52
And n is the number of driving piezoelectric elements.

As shown in FIG. 3, all the piezoelectric elements A ₁ to A ₁
Drives the A _N (n = _N), when the voltage V _X of the DC power source 47 equal to the driving voltage V ₁ of the piezoelectric elements _{A 1 ~A N (V X =} V
_1), as shown by the curve (1), the rise of the voltage of the piezoelectric element becomes as slow, the piezoelectric elements A ₁ to A at time t _N
Rise voltage V of the _N reaches the drive voltage V _1. In contrast, when a high voltage V ₂ than the voltage V _X of the driving voltage V ₁ of the DC power supply _{47 (V X = V 2)} , the voltage V ₂ is voltages V ₁
By higher than, as shown in curve (2), the curve (1) less the slowness of the rise than in the early hours t _N 'than t _N, the rise voltage V of the piezoelectric element A ₁ to A _N reaches to the driving voltage V _1.

Further, to drive one of the piezoelectric elements _{A 1 ~A N (n = 1} ), the piezoelectric element voltage V _X of the DC power source 47 A ₁
If equal driving voltage V ₁ of the to A _N (V _X = V _1), the voltage V of the piezoelectric element, rise as shown by curve (3),
Rise voltage V of the piezoelectric element at time t ₁ reaches the drive voltage V _1. In contrast, when the voltage V _X of the DC power supply 47 and the voltage V ₂ (V _X = V _2), by the voltage V ₂ is higher than the voltage V _1, curve (4) is the curve (3) rising rapidly than in early t ₁ 'than t _1, the rising voltage V of the piezoelectric element reaches the driving voltage V _1.

As is apparent from FIG. 3, the time required for the rising voltage V of the N piezoelectric elements to reach the driving voltage V ₁ and the time required for the rising voltage V of one piezoelectric element to reach the driving voltage V ₁ . in the difference between the time required for the time difference (t _N -t ₁₎ time difference than (t _N '-t _1')
Time is shorter. That is, when a high voltage V ₂ than the voltage V _X of the driving voltage V ₁ of the DC power source 47, resulting in the voltage V of the piezoelectric element to alleviate the variation time to reach the driving voltages V _1.

Further, by the Zener diode 51 of the Zener voltage V ₁ is connected between the output terminals 49 and 50 of the power supply circuit 32 is greater than the drive voltage V ₁ of the piezoelectric element voltage V _X of the DC power supply 47 even (dashed part of the curve (1) and (3)) is not applied voltage exceeding the driving voltages V ₁ to the piezoelectric elements a ₁ to a _N as V _2, is maintained in the driving voltages V _1, the piezoelectric element No failure occurs.

Actually, 16 piezoelectric elements having a drive voltage V ₁ of 20 V are driven by the power supply circuit shown in FIG.
= 16), when a 30V voltage V _X of the DC power supply 47,
As shown in FIG. 6, a time t ₁₆ ′ required for the rising voltage V of the piezoelectric element to reach the driving voltage V ₁ (V ₁ = 20 V).
Was 2.58 usec. When one piezoelectric element is driven (n = 1), the time t ₁ ′ required for the rising voltage V of the piezoelectric element to reach the drive voltage V ₁ (V ₁ = 20 V) is 0, as shown in FIG. .26 usec.
From these results, the difference between t ₁₆ ′ and t ₁ ′ (t ₁₆ ′ −
If t ₁ ′) is taken, it becomes 2.32 usec. That is, the variation time of the rise is 2.32 usec.

[0020] On the contrary, by the power supply circuit is not connected to the Zener diode shown in FIG. 5, the driving voltage V ₁ is 2
The piezoelectric element is 0V 16 pieces drives (n = 16), when a 20V voltage V _X of the DC power supply 47, drive rising voltage V of the piezoelectric element as shown in FIG. 8 voltage V ₁ (V ₁ = 2
0V), the time t ₁₆ required to reach 7.64 use
c. When one piezoelectric element is driven (n =
1), time t required for the rising voltage V of the piezoelectric element to reach the driving voltage V ₁ (V ₁ = 20 V) as shown in FIG.
₁ was 0.99 usec. That is, t ₁₆ and t ₁
The rise variation time, which is the difference (t ₁₆ −t ₁ ), is 6.65 usec.

FIG. 10 shows these results. Thus, the voltage V _X of the DC power supply 47 is set higher than the drive voltage V ₁ of the piezoelectric element _{(V 1 = 20V) (V} X = 30
V), by connecting the Zener diode 51 having a Zener voltage equal to the driving voltage V ₁ of the piezoelectric element (V ₁ = 20 V) to the output terminals 49 and 50 of the power supply circuit 32, the variation in the rise of the voltage V of the piezoelectric element is obtained. You can save time. Further, the power supply circuit 32 includes a power supply circuit 32.
And a Zener diode 51 to the output terminal 49 and 50, the voltage V _X of the DC power supply 47 is only higher than the drive voltage V ₁ of the piezoelectric element, reducing its construction is very simple, also relatively low costs be able to.

[0022]

As described above, according to the first aspect of the present invention, a piezoelectric element drive circuit having a plurality of piezoelectric elements connected in parallel and a switching element connected in series to each piezoelectric element, A power supply circuit having a DC power supply for supplying power to the piezoelectric element, a drive circuit of an inkjet head for discharging the ink by applying a voltage of the DC power supply to each piezoelectric element by conducting each switching element, A Zener diode having a Zener voltage equal to the drive voltage of the piezoelectric element is connected between the power supply output terminals of the power supply circuit, and the voltage of the DC power supply is set to be higher than the drive voltage of the piezoelectric element. Even if there is a change in the number of piezoelectric elements to be made, variations in how the voltage rises can be reduced, and a decrease in print quality can be suppressed. Further, a Zener diode is connected between the power supply output terminals of the power supply circuit, and the voltage of the DC power supply is simply made higher than the drive voltage of the piezoelectric element, so that the configuration is very simple and the cost is kept low. Can be.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a driving circuit of an inkjet head according to the present invention.

FIG. 2 is a detailed circuit diagram of a power supply circuit in FIG.

FIG. 3 is a graph showing a voltage change of a piezoelectric element when a voltage is applied to the piezoelectric element.

[Figure 4] and the pulse signal D, the print signal 1 ^#, and 2 ^#, transistors 13 to 16 are explanatory views for explaining the timings of the piezoelectric elements A _1, A _2.

FIG. 5 is a circuit diagram showing a conventional power supply circuit.

FIG. 6 shows that the number of piezoelectric elements driven by the power supply circuit 32 is one.
6 is a graph showing the voltage V of the piezoelectric element when the voltage is set to 6;

FIG. 7 shows that the number of piezoelectric elements driven by the power supply circuit 32 is one.
6 is a graph showing the voltage V of the piezoelectric element when the voltage V is set to V.

8 is a graph showing a voltage V of a piezoelectric element when the number of piezoelectric elements driven by the conventional power supply circuit of FIG. 5 is set to 16;

9 is a graph showing a voltage V of a piezoelectric element when the number of piezoelectric elements driven by the conventional power supply circuit of FIG. 5 is set to 1;

FIG. 10 is a table showing the results of FIGS. 6 to 9;

FIG. 11 is a circuit diagram showing a conventional inkjet head drive circuit.

FIG. 12 is a graph showing a rise in voltage of a piezoelectric element when a voltage is applied to a plurality of piezoelectric elements.

[Explanation of symbols]

A ₁ to A _N piezoelectric elements 32 feed circuit 47 DC power supply 51 Zener diode

Claims (1)

[Claims] A piezoelectric element driving circuit having a plurality of piezoelectric elements connected in parallel and a switching element connected in series to each piezoelectric element; and a power supply circuit having a DC power supply for supplying power to the piezoelectric elements. A drive circuit for an ink jet head that applies the voltage of the DC power supply to each piezoelectric element by discharging each switching element to discharge ink, wherein a zener diode having a zener voltage equal to the drive voltage of the piezoelectric element is provided. A drive circuit for an ink jet head, wherein the drive circuit is connected between a power supply output terminal of the power supply circuit and a voltage of the DC power supply is higher than a drive voltage of the piezoelectric element.