JP2734528B2 - Electrostatic recording head - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to an electrostatic recording head, and more particularly, to an ion generating section comprising a discharge electrode and an induction electrode;
The present invention relates to an electrostatic recording head used for, for example, a printer or a facsimile, including an ion flow control unit formed by a screen electrode.

[Prior Art] As this type of conventional electrostatic recording head, an electrostatic recording head that generates ions and records an image with the ions is known (US Pat. No. 4,408,214).

As shown in FIG. 4, the electrostatic recording head is provided with an induction electrode 14 disposed via an insulating substrate 13 on a head base 12 provided with a heater 11 heated by a heating source 11a on the back.
An ion generator 10 comprising an AC power supply 17 for applying an AC high voltage between the induction electrode 14 and a discharge electrode 16 superposed on the induction electrode 14 via a first insulating layer 15; Ion flow control formed by a screen electrode 22 provided thereon with a DC voltage applied from a DC reverse bias power supply 19 disposed between the discharge electrode 16 and the second insulating layer 18. And a section 20. More specifically, as shown in FIGS. 5 and 6, the ion generating section 10 drills a plurality of induction electrodes 14, 14... Arranged in parallel with each other and a large number of ion generating holes 16a, 16a. And the discharge electrodes 16, 16,... Arranged in parallel with each other in an inclined manner are arranged in a matrix to form a space region 16b. Further, the ion flow control unit 20 is connected to a screen electrode 22 that is bonded and fixed to the surface of the discharge electrodes 16, 16,... Of the ion generation unit 10 with an adhesive (not shown) via a second insulating layer 18. Hole 16 for ion generation
Openings 23, 23 ... that match the a, 16a ... and the spatial regions 16b, 16b ...
Are provided to form the ion flow passage 24.

Reference numeral 26 denotes a thermocouple for detecting the temperature of the ion flow passage 24, and a signal from the thermocouple 26 is used as a heating source of the heater 11.
11a.

In the conventional electrostatic recording head configured as described above, the AC high voltage from the AC power supply 17 is applied to the induction electrodes 14 and 14.
… And the discharge electrodes 16, 16,…
Surface corona discharge occurs in the space region 16b of the discharge electrode 16, and positive and negative ions are generated due to dielectric breakdown in the space region 16b. In this state, when the switching element is turned on, only negative ions are charged based on the electrostatic field formed between the discharge electrode 16 and the screen electrode 22 and the potential level of the screen electrode 22 (not shown). )
When the switching element is turned off, no electrostatic field is formed, and the ions in the ion flow passage 24 are neutralized and spontaneously disappear.

In the electrostatic recording head configured as described above,
It is known that heating the head has the effect of improving output, preventing electrode corrosion, and extending the product life.

[Problems to be Solved by the Invention] However, in this type of recording head, the first insulating layer 15 of the ion generator 10 is generally made of, for example, ceramics such as alumina and zirconia, or inorganic materials such as glass and mica. On the other hand, as the screen electrode 22, for example, one obtained by etching a thin plate of stainless steel, nickel steel, or the like is used. Therefore, when the recording head is heated and used,
Due to the difference in the coefficient of thermal expansion between the first insulating layer 15 and the screen electrode 22, the gap 23 between the discharge space region 16b and the screen electrode 22 is formed.
(See FIG. 8). The magnitude of the position shift 28 is 1/1 of the recording resolution pitch.
It is desirable that it be 2 or less, for example, 50 μm or less at 240 spi (spot per inch) and 40 μm at 300 spi
It is considered that the following is desirable, and above that, the output may be reduced, or the density or unevenness of the recorded image may be reduced.
There is a fear that blurring or the like may occur.

The displacement 28 is caused by the first insulating layer 15 and the screen electrode.
Although it depends on the difference in the coefficient of thermal expansion of the 22 materials and the temperature difference between when manufacturing the head and when using the head, in general, the temperature when manufacturing the head is about 20 ° C, and the temperature when using the head is about 60 ° C to 75 ° C. When the temperature difference is about 40 ° C to 55 ° C,
The sample No. 28 was not less than 1/2 of the recording resolution pitch, and was not satisfactory in the accuracy of the recording head and the like.

The present invention has been made in view of the above circumstances, and has as its object the difference in thermal expansion coefficient between the insulating layer of the ion generation unit constituting the electrostatic recording head and the screen electrode material of the ion flow control unit. Eliminating the positional displacement between the discharge electrode side space area and the opening of the screen electrode due to the temperature difference between when the head is manufactured and when the head is used, it is possible to reduce a decrease in output, a decrease in density of a recorded image, and prevention of unevenness and blurring. It is an object of the present invention to provide such an electrostatic recording head.

[Means for Solving the Problems] In order to achieve the above object, an electrostatic recording head according to the present invention includes an induction electrode provided on a head base provided with a heating means via an insulating substrate, and an induction electrode provided on the head base. An ion generating section for generating a creeping corona discharge in a space region of the discharge electrode by applying an AC high voltage between the discharge electrode and the discharge electrode which is superposed on the electrode via the first insulating layer; At the time of manufacture of an electrostatic recording head comprising: an ion flow controller formed by a screen electrode provided with a second insulating layer and a DC voltage applied between the discharge electrode and the discharge electrode. The first insulating layer of the ion generating section and the screen electrode are formed of a material capable of absorbing the amount of displacement due to the thermal expansion between the first insulating layer of the ion generating section and the screen electrode due to the temperature difference during use. Used with The ion generator and the screen electrode are bonded and fixed by elastic bonding means so that the total lengths of the ion generator and the effective recording section of the screen electrode at the time can match each other.

In the present invention, the elastic bonding means may be of any type as long as it has elasticity capable of absorbing a displacement based on thermal expansion of the insulating layer and the screen electrode of the ion generating section. An adhesive tape based on a heat-resistant material such as a silicone-based or vinyl acetate-based adhesive, a rubber-based or resin-based adhesive, preferably Teflon (trade name) or polyimide can be used. Also,
The bonding mode of the adhesive may be such that the insulating layer of the ion generating section and the screen electrode are entirely or partially bonded to each other, or may be bonded to both sides of the screen electrode along the longitudinal direction. .

[Operation] According to the electrostatic recording head of the present invention configured as described above, the amount of displacement based on the thermal expansion of the first insulating layer of the ion generating unit and the screen electrode due to the temperature difference between the time of manufacture and the time of use. Since the first insulating layer and the screen electrode of the ion generating section are formed of a material capable of absorbing the heat and are attached to the ion generating section by means of an elastic bonding means, ion emission due to thermal expansion when the head is used. To prevent misalignment of the
It is possible to prevent an adverse effect such as a decrease in output due to displacement.

Embodiment An embodiment of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a plan view of the electrostatic recording head of the present invention.

Since the basic configuration of the electrostatic recording head of the present invention is the same as that of the conventional electrostatic recording head shown in FIG. 4, the same parts are denoted by the same reference numerals, and the description thereof will be omitted. The features of the invention will be described.

The screen electrode 22 constituting the ion flow control unit 20 of the electrostatic recording head according to the present invention is formed of a rectangular thin plate made of stainless steel or nickel steel. Constituting discharge electrode 16
Are provided with a number of holes 23, 23 ... which can match the air holes 16a, 16a ... and the air regions 16b, 16b .... The screen electrode 22 is formed on the surface of the second insulating layer 18 in which the discharge electrode 16 constituting the ion generating part 10 is embedded using an adhesive tape 30 based on a heat-resistant material such as Teflon (trade name) or polyimide. It is attached to.

To combine the screen electrode 22 and the ion generator 10, for example, after accurately aligning the center of the screen electrode 22 and the ion generator 10 using a fine moving table device having a manipulator device or a micrometer, etc. What is necessary is just to adhere | attach both.

In this case, the total length of the effective recording section of the ion generating section 10 (specifically, the insulating substrate 13) at the temperature (20 ° C.) at the time of manufacturing the head is L ₁ (see FIG. 2). The total length of the recording section is defined as L ₂ (see FIG. 3), and the total length of the effective recording section of the ion generating section 10 at the temperature when the head is used.
Assuming that L ₁ ′ and the total length of the effective recording portion of the screen electrode 22 are L ₂ ′, the temperature of the ion generating portion 10 at the temperature at the time of head manufacture is such that L ₁ ′ = L ₂ ′ at the temperature at the time of head use. determining the total length L ₂ 'of the effective recording portion of the overall length L ₁ and the screen electrode 22 of the effective recording section. That is, the coefficient of thermal expansion of the material of the first insulating layer 15 of the ion generator 10 is α ₁ , and the screen electrode
The coefficient of thermal expansion of the material No. 22 was α2, and the temperature during head manufacture was 20
Assuming that the temperature when the head is used is t ° C. and the total length L ₁ ′ of the effective recording portion of the ion generating section 10 at the temperature when the head is used.
L ₁ ′ = L ₁ (1 + α ₁ ) (t−20) Also, the screen electrode 22 at the temperature when the head is used is
The total length L2 of the effective recording portion _{'of, L 2' = L 2 (} 1 + α 2) (t-20) ... and since, from the equation and equation, positional deviation E = L ₂ of the ion emitting unit '-L _1' = 0 so as to determine the size of the full length L ₁ and L ₂ of the effective recording of the full-length and screen electrode 22 of the effective recording of the ion generator 10.

Therefore, in order to set the dimensions of L ₁ and L ₂ ,
First, when the screen electrode 22 is formed of stainless steel or nickel steel, and the first insulating layer 15 of the ion generator 10 is formed of natural white mica or 96% alumina, the head is manufactured and used. Since the thermal expansion deformation at the temperature difference is a numerical value as shown in Table 1, this numerical value is taken into consideration.

In the case of a head capable of recording an A4 short size (210 mm width) at a resolution of 300 spi, for example, the total number of dots is set to 2,560.
Since the total length of the effective recording section as dots is 216.747 mm, the total length of the effective recording section when the head is used needs to be 216.747 mm in consideration of the temperature difference between when the head is used and when the head is manufactured.

In view of the above, the total lengths L ₁ and L ₂ of the effective recording portion when each material was used for the first insulating layer 15 and the screen electrode 22 of the ion generation portion 10 were obtained. Numerical values were obtained.

Therefore, the first insulating layer 15 and the screen electrode 22
By properly selecting the material and the total length L ₁ , L ₂ of the effective recording section at the time of manufacturing, it is possible to absorb the displacement of the ion emitting section due to the thermal expansion due to the temperature difference between the time of manufacturing the head and the time of using the head. And the recording resolution pitch can be set to 1/2 or less.

Although thermal expansion deformation occurs in the width direction of the screen electrode 22 and displacement occurs, the width direction of the screen electrode 22, that is, the width direction of the head is usually about 1/40 or less as compared with the thermal expansion deformation in the longitudinal direction. Is small, so it can be ignored.

In the above embodiment, the case where the ion generating unit 10 and the screen electrode 22 are adhered with the adhesive tape 30 has been described.However, the present invention is not necessarily limited to the case where the adhesive unit 30 is adhered with the adhesive tape 30. The second insulating layer 10 is made of a relatively elastic synthetic rubber, silicone or vinyl acetate adhesive so as to absorb the amount of thermal expansion between the first insulating layer 15 and the screen electrode 22.
The insulating layer 18 and the screen electrode 22 may be bonded.

[Effects of the Invention] As described above, according to the electrostatic recording head of the present invention, the material capable of absorbing the amount of displacement due to the thermal expansion of the first insulating layer of the ion generating portion and the screen electrode during use. The insulating layer of the ion generating section and the screen electrode are formed at the same time, and the ion generating section and the screen electrode are elastically bonded so that the entire lengths of the effective recording section of the ion generating section and the screen electrode in use can match each other. The following effects can be obtained by bonding and fixing by means.

1) It is possible to eliminate the displacement between the ion generating section and the ion emitting section due to the thermal expansion of the screen electrode due to the temperature difference between when the head is used and when the head is manufactured.

2) According to the above 1), the magnitude of the positional shift of the ion emitting portion can be reduced to half or less of the recording image pitch, and it is possible to prevent a decrease in the density of the recording image, unevenness and blurring of the image, and the like.

[Brief description of the drawings]

FIG. 1 is a plan view of a first embodiment of the electrostatic recording head of the present invention, FIG. 2 is a plan view of an ion generating section of the present invention,
FIG. 3 is a plan view of a screen electrode according to the present invention, FIG. 4 is a sectional view showing a principle structure of the electrostatic recording head, FIG. 5 is a sectional view of an ion generating portion of the electrostatic recording head, and FIG. FIG. 7 is a plan view of a generating unit, FIG. 7 is a plan view of a conventional electrostatic recording head, and FIG. 8 is an enlarged cross-sectional view showing a displacement of an ion emitting unit of the electrostatic recording head. Description of symbols (10) ... Ion generator (11) ... Header (12) ... Head substrate (13) ... Insulating substrate (14) ... Induction electrode (15) ... First insulating layer (16) ... Discharge electrode (16a) ... Ion generation hole (16b) ... Space area (17) ... AC power supply (18) ... Second insulating layer (19) ... DC reverse bias power supply (20) ... ... Ion flow control unit (22) ... Screen electrode (23) ... Open hole (24) ... Ion flow passage (30) ... Adhesive tape (adhesion means)

Claims (1)

(57) [Claims] An induction electrode disposed on a base of a head provided with a heating means via an insulating substrate, and a discharge electrode arranged on the induction electrode via a first insulating layer in an overlapping manner. An ion generating section that generates a creeping corona discharge in the space region of the discharge electrode by applying an AC high voltage, and a DC current is disposed between the discharge electrode and the ion generation section that is disposed on the discharge electrode via a second insulating layer. In an electrostatic recording head comprising an ion flow control unit formed by a screen electrode to which a voltage is applied, the first insulating layer of the ion generation unit and the screen electrode at a temperature difference between during manufacture and during use. The first insulating layer of the ion generator and the screen electrode are formed of a material capable of absorbing the amount of displacement due to thermal expansion, and the total lengths of the ion generator and the effective recording section of the screen electrode during use match each other. Achievable Electrostatic recording head, characterized by comprising adhered and fixed by an adhesive means having elasticity and an ion generating unit and the screen electrode as.