JPH0647991A - Recording device - Google Patents

Abstract

PURPOSE:To enable a rise in temperature of a thermal head to be prevented in a simple structure without the necessity of enlarging the apparatus in size by providing a heat conducting part which transfers a heat of the thermal head to one of the outer jacketing part and frame, between one of the outer jacketing part and inner frame of an apparatus main body and a thermal head foundation part. CONSTITUTION:A heat conducting part 12 for transferring the heat of a thermal head 3 onto an upper cover 1 is provided between the head foundation part 3A of a thermal head 3 and the upper cover 1 to be an outer jacketing part of the apparatus main body. Next, the heat conducting part 12 is made by bending a planar material having fine heat conductivity, of iron, aluminum, copper, and the like, and then provided between the head foundation part 3A and the upper cover 1. The heat conducting part 12 is fastened by a screw or the like on the head foundation part 3A and upper cover 1, or simply placed into contact therewith. Subsequently, heat of the head foundation part 3A is transferred to the heat conducting part 12 and, further, to the upper cover 1 and finally discharged outside. Ordinarily, the quantity of heat discharge is generally proportional to the area of a heat acceptor (upper cover 1), and therefore a quantity of heat discharge tends to Increase as the area is larger.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording apparatus using a thermal head, which is configured as a copying machine, a printer, a facsimile or the like.

[0002]

2. Description of the Related Art Among various recording apparatuses, a recording apparatus using a so-called line type thermal head is known. FIG. 10 shows an example of the thermal transfer printer. In the recording apparatus 10 of this example, the inside of the apparatus is covered with an upper cover 1 and a lower cover 2, and inside this, a thermal head 3, a platen roller 4, a paper feed cassette 5, a paper discharge tray 6 and the like are respectively shown. It is provided at each position. Of these, the thermal head 3 is attached to a head support spring 8 whose base end is fixed to the frame 7. Then, the thermal head 3 uses an ink sheet (not shown) at the time of recording.
And the recording paper (not shown) sent from the paper feeding cassette 5 to press the platen roller 4 by the action of the head pressure spring 9, and the heating element of the thermal head 3 responds to the image signal at this time. As a result, the ink in the ink sheet is melted or sublimated and transferred onto the recording paper.

The thermal head 3 has a head base portion 3A made of a material such as metal so that the head itself has rigidity or performs a heat radiation function. By the way, among recording apparatuses using this type of thermal head 3, particularly in a sublimation type thermal transfer printer, a large amount of heat is required for transfer, so that the head base portion 3A easily accumulates heat.

Unless the head is cooled and controlled in some way to suppress the accumulated heat, the following problems occur.

(1) Due to the heat storage, the amount of heat applied to the ink sheet in the head heater section increases, and the image quality deteriorates. In particular, when performing multi-gradation expression or the like, so-called thermal modulation is performed by changing the temperature of the heater portion. However, if the above-described heat storage occurs, such gradation control becomes difficult.

(2) Depending on the pitch condition between each recording dot, the history condition of the recording dots, the surrounding environmental conditions, etc.
When changing the applied voltage, the applied pulse width, the number of pulses, etc., if the heat storage as described above occurs, the control system becomes more complicated, the device becomes bulky, or continuous printing can be endured. It will disappear.

In any case, since an integrated circuit or the like is mounted on this type of thermal head, it is necessary to suppress the head temperature so that the temperature does not exceed the temperature for guaranteeing this operation. For example, about 70 ° C. is the limit, although it depends on the conditions.

However, especially as the recording apparatus is downsized, the space inside the apparatus body is also narrowed, so that the heat dissipation effect of the thermal head is reduced, and heat is easily accumulated in the thermal head. Therefore, for cooling control of the head, a method using a means such as a heat pipe is also proposed, but with this method, the internal volume of the recording apparatus tends to increase,
The main body of the apparatus becomes large and the cost becomes high.

Incidentally, as a related technique of this kind, the actual development 6
Those disclosed in Japanese Patent Laid-Open Nos. 0-119546, 62-83154, 61-261083, and 64-7592 have already been proposed.

[0010]

SUMMARY OF THE INVENTION An object of the present invention is to have a relatively simple structure and without increasing the size of the device.
It is an object of the present invention to provide a recording device capable of preventing the temperature rise of the thermal head.

[0011]

In order to achieve the above object, the present invention provides a recording apparatus using a thermal head,
A recording apparatus having a heat conduction section for transmitting heat of the thermal head to at least one of the exterior section and the frame between the thermal head base section and at least one of the exterior section of the apparatus main body and the frame inside thereof. It is a proposal.

It is effective to provide the heat conducting portion with a row of protrusions for increasing the heat radiation area.

Further, the heat conducting portion has a heat radiating fin portion and is connected to the head base portion, and heat is applied from the first heat conducting portion to at least the exterior portion and the frame. It is effective if it is configured with the second heat conducting portion that is transmitted to one side.

Further, when the heat conducting portion has flexibility,
It is effective.

Furthermore, if at least one of the exterior portion and the frame has a fin portion, and the heat conducting portion is a heat conducting portion provided with a fin portion that relatively slides on the fin portion, It is effective.

Further, it is effective that at least one of the exterior portion and the frame is provided with a row of protrusions for increasing the heat radiation area.

Further, it is effective that at least one of the exterior portion and the frame is made of a high heat conductive material.

Further, it is effective to position the heat conducting portion in the forced air passage that circulates inside and outside the apparatus body.

Further, the heat conducting portion is configured to contact at least one of the exterior portion and the frame and the head base portion, and a heat conducting viscous material or a heat conducting elastic material is provided at each contacting portion. This is effective.

[0020]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 shows a schematic configuration of a recording apparatus 10 using a thermal head according to an embodiment of the present invention. The basic configuration of this recording apparatus is the same as that of the conventional recording apparatus described with reference to FIG. There is no change. Therefore, the description regarding these is omitted. The difference from the conventional recording apparatus is that a heat conducting section 12 that transfers the heat of the thermal head 3 to the upper cover 1 is provided between the head base portion 3A of the thermal head 3 and the upper cover 1 which is the exterior portion of the apparatus main body. It is at the point of interposition.

In the embodiment shown in FIG. 1, the heat conducting portion 12 is formed by bending a plate-shaped material having good heat conductivity such as iron, aluminum or copper. ,
It is provided between the head base portion 3A and the upper cover 1.
The heat conducting portion 12 is fastened to the head base portion 3A and the upper cover 1 with a screw or the like, or simply abuts.

Further, as shown in FIG. 2, a part of the upper cover 1 which is an exterior part is formed by recessing the bottom part of the head base part 3.
The upper cover portion may be used as the heat conducting portion 12 by being fastened or simply abutted on A.

The arrows in FIGS. 1 and 2 indicate the heat transfer paths, and the heat of the head base portion 3A is the heat conducting portion 1.
The heat transmitted to the heat conducting section 12 and to the heat conducting section 12 is further transmitted to the upper cover 1 and is discharged to the outside from here. Usually, the amount of heat dissipation is determined by the heat acceptor (upper cover 1).
Is approximately proportional to the area, and the larger this area, the greater the amount of heat radiation.

Therefore, the upper cover 1 and the like have an area which is several ten times as large as that of the thermal head 3.
In addition, the heat dissipation effect can be further enhanced by joining or fastening the heat conducting portion 12. Moreover,
Since the upper cover 1 is directly placed in the usage environment space, a further heat dissipation effect can be expected by connecting the heat conducting portion 12 to such an upper cover 1. According to such an embodiment, the thermal head 3 can dissipate heat without using a heat pipe, so that the recording apparatus does not become bulky and the cost does not increase to the left.

As shown in FIG. 3, for example, a plate-shaped heat conducting portion 12 is provided with a row of protrusions 12a to increase the surface area of the heat conducting portion 12 to enhance the heat radiation effect of the heat conducting portion itself. May be. With this, the heat dissipation of the head is further improved. Even if such a row of protrusions is provided on the upper cover 1 itself to increase the surface area, the heat dissipation is further improved. The projection row may have a corrugated shape, a concavo-convex shape, or any other suitable shape, and cut and raised pieces may be formed in an array. Such a configuration of the projection row can be similarly adopted when the heat conducting portion 12 is formed by the upper cover itself as shown in FIG.

The frame 7 is arranged inside the apparatus main body,
The thermal head 3 and other printing equipment housed inside the thermal head 3 are mounted. A thermal conduction part is provided between the frame 7 and the head base portion 3A of the thermal head 3 to provide the thermal head. It is also possible to dissipate the heat generated in 3. Further, a heat conducting portion may be provided between both the exterior portion such as the upper cover 1 and the frame 7 and the head main body portion 3A to further enhance the heat radiation effect. According to the present invention, a heat conduction unit that transfers heat of a thermal head to at least one of the exterior portion and the frame is provided between at least one of the exterior portion of the apparatus main body and the frame inside thereof and the head base portion of the thermal head. It is provided.

In the embodiment shown in FIG. 4, a heat conducting portion 22 is provided between the frame 7 and the head base portion 3A.

The heat conducting portion 22 is the head base portion 3A.
And a frame 7 or both, and is fastened with a screw or the like. The frame 7 is usually made of a rigid metal plate, has good thermal conductivity, and has a large surface area.
Even if the heat conducting portion 22 is connected, the heat radiation effect can be enhanced similarly to the upper cover 1 having a large surface area.
In the case of this example, it is effective when the upper cover 1 is made of a synthetic resin molded product or the like having poor thermal conductivity for design or design reasons.

When both the upper cover 1 and the frame 7 are made of a material having a high thermal conductivity, such as aluminum, copper, and iron, as described above, the heat conducting portion is covered by the upper cover. Both 1 and the frame 7 can be brought into contact with or fastened together. In addition, the frame 7 itself may be provided with a row of protrusions as shown in FIG. 3 to increase the heat radiation area. As described above, the projection row for increasing the heat radiation area can be provided on at least one of the exterior portion such as the upper cover 1 and the frame 7. Further, the heat conducting portion 22 shown in FIG. 4 is a member separate from the frame 7, but a part of the frame 7 may be configured as the heat conducting portion 22.

In any case, by using a heat receptor (upper cover or frame) having a large surface area, the heat radiation effect is improved, and the saturation temperature of the head is lowered even when continuous printing is performed. This makes it possible to increase the number of continuously printed sheets without degrading the image quality.

As described above, the heat conducting portion is connected to at least one of the upper cover 1 and the frame 7. At this time, at least the upper cover or frame 7 to which the heat conducting portion is connected is made of aluminum, copper or iron. It is composed of a high thermal conductive material that easily transfers heat such as.

FIG. 5 shows another embodiment. In this example, the heat conducting portion 32 is connected (fastened or simply contacted) to the first heat conducting portion 32A having a radiation fin portion 32A _1. The second heat conducting portion 32B is in contact with the second heat conducting portion 32B. The first heat conducting portion 32A is the head base portion 3
The second heat conducting portion 32B is connected (fastened or simply abutted) to the A side, and is connected (fastened or simply abutted) to the frame 7. According to such a configuration, the head base portion 3
The heat of A is transmitted to the frame 7 via the first and second heat conducting portions 32A and 32B, and at this time, the heat radiation fin portion 32A ₁ functions to promote heat radiation. In addition,
The second heat conducting portion 32B may be connected to the upper cover 1, or the second heat conducting portion 32B may be connected to both the upper cover 1 and the frame 7. good. Further, the first heat conducting portion 32A is connected to the head base portion 3A.
Alternatively, the second heat conducting portion 32B may be formed by part of the frame 7 or the upper cover 1.

In this way, the heat conducting portion 32 has the heat radiating fin portion 32A ₁ and is connected to the head base portion 3A, and the first heat conducting portion 32A.
Therefore, the second heat conducting portion 32B that transfers heat to at least one of the exterior portion and the frame 7 is configured.

By the way, in this type of recording apparatus capable of color printing, at the time of thermal transfer recording, the recording paper to be superposed on the color ink sheet is arranged in front of and behind the recording portion for each transfer of different colors. Although it is configured to be reciprocally transported, the thermal head 3 is shown in FIG. 11 in such a case, or at the time of feeding / discharging the recording paper, and at the time of non-recording such as replacement of the ink sheet. Thus, the platen roller 4 is separated from the platen roller 4.

As described above, even in the recording apparatus of the type in which the thermal head 3 is displaced up and down, the above-described heat conducting portions 1
If the materials 2, 22, and 32 are made of a flexible material, the displacement of the thermal head 3 is not hindered. Alternatively, by adopting the following configuration, it is possible to dissipate the heat satisfactorily without inhibiting the vertical displacement of the thermal head.

FIG. 6 shows an embodiment which can cope with such a point. A feature of this embodiment is that a heat conducting portion having flexibility and good heat conductivity is used as the heat conducting portion. What is indicated by reference numeral 42 is the heat conducting portion. In the present example, the heat conducting portion 42 includes the head base portion 3A,
It is arranged so as to be interposed between the upper cover 1 and the upper cover 1. As the heat conducting portion 42, an elastic body such as a bendable leaf spring having a relatively small spring constant, a mesh structure (mesh structure), or a bundle of thin elastic wires in a brush shape is used. Can be mentioned as.

The flexible heat conducting portion connected (fastened or simply abutted) to the head base portion 3A as described above may be connected to the frame 7, or the frame 7 may be connected.
It may be connected to both of the outer cover and the outer cover. Alternatively, this heat conducting portion can be connected to the head base portion 3A via the first heat conducting portion 32A shown in FIG.

In any case, by using a flexible heat conducting portion, the thermal head 3
Even if is displaced up and down, it is possible to expect the good heat dissipation effect described above.

FIG. 7 shows still another embodiment. In this embodiment, a comb-teeth-shaped fin portion 1a extending inside the apparatus main body is provided on an upper cover 1 forming an exterior portion, and a head base portion 3 is provided.
A is provided with a comb-teeth-shaped fin portion 3A ₁ extending toward the fin portion 1a so that both fin portions 1a and 3A ₁ are in contact with each other.

When the thermal head 3 is displaced up and down, the fin portion 3A ₁ slides relative to the fin portion 1a, and the heat of the head base portion 3A is transferred through the relative sliding surface.
Is transmitted to. Each of the fin portions 1a and 3A ₁ promotes the heat radiation effect and functions to enhance the heat radiation effect of the head. In this example, even if the thermal head 3 is displaced up and down, such a function can be achieved.

It should be noted that a fin portion may be provided on the frame 7 provided in the recording apparatus, on which some printing equipment is mounted, and the fin portion 3A ₁ may be engaged with the fin portion 3A _{1 so as} to be relatively slidable. . In any case, each fin portion functions as a heat conducting portion. Further, fin portions are provided on both the exterior portion such as the upper cover 1 and the frame 7,
The fin portion 3A ₁ may be engaged with these. Thus, at least one of the exterior portion and the frame may have the fin portion. Also, in the example of FIG.
The fin portion 3A ₁ is formed on the head base portion 3A itself and constitutes the heat conducting portion. However, even if the heat conducting portion is provided separately from the head base portion 3A and the fin 3A ₁ is formed on it. Good.

FIG. 8 shows an embodiment in which the heat conducting portion is located in a forced air passage that circulates inside and outside the apparatus body. In the examples so far, the heat dissipation of the thermal head was left to the natural heat dissipation, but in the case of this example, a forced air flow is created, and the heat conduction part is positioned in it. The forced cooling method is used together.

A ventilation opening 1b is provided in the upper cover 1, a ventilation opening 1c is provided in a side portion of the upper cover 1, and a fan 11 is installed inside the opening 1c. When the fan 11 operates, a forced air passage is formed from the ventilation opening 1b toward the exhaust opening 1c, and the air flowing through this portion is interposed between the upper cover 1 and the head base portion 3A. The heat conducting portion 42 is forcibly cooled.

In this example, as the heat conducting portion, a heat conducting portion which is elastically deformable as shown by reference numeral 42 is adopted, but instead of this, any of the above-mentioned types of heat conducting portions is used. You can also In any case, by forcibly cooling such a heat conducting portion, the heat dissipation effect of the head is further improved. Further, in the case of this configuration, since the thermal head 3 itself is also located in the air passage, this direct cooling can be performed at the same time. The fan 11 may be configured to suck in the outside air, and the wind may flow in the air passage.

By the way, in FIG. 8, the upper cover 1 is
If the lower cover 2 or another frame is fitted, the positional error of the upper cover is apt to occur. When the heat conducting portion 42 is fastened to both the upper cover 1 and the head base portion 3A with screws or the like, the upper cover 1
If there is an error in the position of, it becomes difficult to attach the heat conducting portion with high accuracy.

The embodiment shown in FIG. 9 shows an example of a recording apparatus in consideration of such a point. A lid member 13 is attached to the upper cover 1 with screws 14, and the lid member 13 has screws 14
Before it is fastened, it can move back and forth and left and right. With the upper cover 1 fitted, the lid member 13 is moved and adjusted to the left or right or front and back, and then the screw 14 is fastened to fasten the heat conducting portion 42. With this configuration, the heat conducting portion 42 can be easily and accurately fastened on the basis of the position on the head side. This structure can also be applied when the above-mentioned various types of heat conducting parts are used.

The heat conducting portion 42 is connected to the head base portion 3A.
When it is interposed between the frame 7 and the frame 7, the heat conducting portion can be fastened to the frame via some intermediate member that can move relative to the frame 7.

By the way, in the series of embodiments described so far, the joint between the heat conducting portion and the head base portion, and
At the joint between the heat conducting portion and the upper cover and at the joint between the heat conducting portion and the frame, heat transfer loss is likely to occur due to the influence of minute surface irregularities and poor surface accuracy.

In this way, when the heat conducting portion is configured to be in contact with at least one of the exterior portion such as the upper cover 1 and the frame 7 and the head base portion 3A, for example, a layered structure is formed at each of the joining portions. If a heat-conductive viscous material or a heat-conductive elastic material (heat sinker) such as silicone rubber, which is formed in the above, is interposed, heat transfer loss at the joint surface can be suppressed. Needless to say, such a configuration can be adopted when the heat conducting portion of each of the above-described embodiments is used and also in the sliding portion between the fin portions shown in FIG. 7.

The recording apparatus may be configured by appropriately combining the above-described configurations. Further, each of the above-described configurations can be applied to various devices that can generate high heat, such as heat radiation of a heat roller of an image forming apparatus and heat radiation of a scanner fluorescent tube.

[0052]

According to the structure described in claim 1, the thermal head can radiate heat with a relatively simple structure and without making the apparatus bulky, and the temperature rise can be effectively performed. Can be suppressed.

According to the second aspect, the heat dissipation effect of the thermal head can be further improved.

According to the third aspect of the invention, the heat dissipation of the thermal head can be further improved.

According to the structure described in claim 4, even if the thermal head is displaced up and down, the thermal head can radiate heat well.

According to the fifth aspect, the thermal head can satisfactorily radiate heat even if the thermal head is displaced up and down.

According to the structure of claim 6, the heat dissipation area is increased, and the heat dissipation of the thermal head can be further improved.

According to the structure described in claim 7, the heat transfer efficiency can be increased, and hence the heat dissipation effect of the thermal head can be further improved.

According to the eighth aspect of the present invention, since the air cooling is used together, the heat dissipation of the thermal head can be further improved.

According to the ninth aspect of the invention, heat transfer loss at the joint surface is less likely to occur, and the heat dissipation of the thermal head can be further improved.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional configuration diagram of a recording apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic cross-sectional configuration diagram of a recording apparatus having a heat dissipation portion of another form.

FIG. 3 is a cross-sectional view showing another example of the heat conducting portion.

FIG. 4 is a schematic sectional view of a recording apparatus according to another embodiment.

FIG. 5 is a schematic cross-sectional view of a recording apparatus according to another embodiment.

FIG. 6 is a schematic configuration sectional view of a recording apparatus according to still another embodiment.

FIG. 7 is a cross-sectional view of a configuration of a heat transfer portion of yet another embodiment.

FIG. 8 is a schematic sectional view of a recording apparatus according to another embodiment.

FIG. 9 is a schematic structural cross-sectional view of a recording apparatus of still another embodiment.

FIG. 10 is a schematic cross-sectional view of a conventional recording device.

FIG. 11 is a diagram showing a state in which the thermal head of the recording apparatus is separated from the platen roller.

[Explanation of symbols]

1a Fin part 3 Thermal head 3A ₁ Fin part 3A Head base part 3A ₁ Fin part 7 Frame 10 Recording device 12 Heat conduction part 12a Protrusion row 22 Heat conduction part 32 Heat conduction part 32A First heat conduction part 32A ₁ Radiation fin part 32B 2nd heat conduction part 42 Heat conduction part

Claims (9)

[Claims] 1. In a recording apparatus using a thermal head, the heat of the thermal head is transferred between at least one of the exterior section of the apparatus main body and the frame inside the thermal head base section, and the heat of the exterior section and the frame. A recording apparatus, characterized in that a heat conducting section for transmitting to at least one side is provided. 2. The recording apparatus according to claim 1, wherein the heat conducting portion is provided with a row of protrusions for increasing a heat radiation area. 3. A first heat conducting portion, wherein the heat conducting portion has a radiation fin portion and is connected to the head base portion, and the first heat conducting portion.
The second heat conducting portion configured to transfer heat from the heat conducting portion to at least one of the exterior portion and the frame.
Or the recording device according to 2. 4. The heat conducting section is flexible.
The recording device according to any one of 1 to 3. 5. The heat conducting portion is a heat conducting portion having a fin portion which relatively slides relative to the fin portion, at least one of the exterior portion and the frame having a fin portion. The recording apparatus according to any one of 1 to 4. 6. At least one of the exterior portion and the frame,
The recording apparatus according to any one of claims 1 to 5, further comprising a row of protrusions for increasing a heat radiation area. 7. At least one of the exterior portion and the frame,
The recording apparatus according to claim 1, wherein the recording apparatus is made of a material having high thermal conductivity. 8. The recording apparatus according to claim 1, wherein a heat conduction section is located in a forced air passage that circulates inside and outside the apparatus body. 9. The heat conducting portion is configured to contact at least one of the exterior portion and the frame and the head base portion, and a heat conducting viscous material or a heat conducting elastic material is provided at each contacting portion. The recording device according to claim 1.