JPH0294384A - Ceramic heater with heat radiating fin - Google Patents

Abstract

PURPOSE:To provide an excellent heat emitting characteristic with high output by using a ceramic heater formed by embedding a heat emitting resistor in a ceramic, and inserting and fixing this ceramic heater into a mounting hole of a heat radiating fin formed from a plurality of metal plates. CONSTITUTION:In a ceramic heater 1, a heat emitting resistor 1a is embedded in a ceramic and equipped with a lead 3 for current supply to the resistor 1a. A heat radiating fin 2 is made from a metal plate, which is light and has good thermal conductivity, and must excel in the warm wind generating characteristic to conduct and radiate the heat generated by the ceramic heater 1 in good performance. This radiating fin 2 is provided with a mounting hole 2a, and the ceramic heater 1 provided with a metallized layer 1b is inserted into the mounting hole 2a, followed by brazing to secure the ceramic heater 1 and radiating fin 2 together. A bend 2b is formed in the mounting hole 2a, and the fin 2 and ceramic heater 1 are fixed firmly at this bend 2b. This achieves excellent heat radiating characteristic with high output.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a ceramic heater with radiation fins used in hot air heaters and the like.

[Conventional technology]

Conventionally, hot air heaters have a positive resistance temperature characteristic of P.
A TC heater with aluminum radiation fins fixed to it was used. (For example, Tokuko Sho 61-17351
(Refer to No. 62-48350) This is a PT made of barium titanate ceramics as shown in Figure 8.
Electrodes 12 were formed on both sides of the C heater 11, and radiation fins 13 formed by bending an aluminum plate were further fixed.

This PTC heater 11 is energized by a power source 14 to generate heat, and air is passed through the radiation fins 13 to generate warm air. In addition, the PTC heater 11
has a positive resistance-temperature characteristic, and has the property that the resistance value increases rapidly at a certain temperature and can prevent the temperature from rising further.

[Issues with conventional technology]

However, due to its characteristics, the conventional PTC heater with radiation fins as described above has a low calorific value (,97n++++X66
1111Ii or 148mm x 44mm when used as a hot air heater at most 1200-
However, only a moderate output could be obtained, and a high-output hot air heater could not be obtained.

[Means to solve the problem]

In view of the above, the present invention uses a ceramic heater in which a heating resistor is embedded in a ceramic body, and radiates fins made of a plurality of metal plates are directly attached to the ceramic heater, or the ceramic heater is mounted in a metal case. A plurality of metal heat radiation fins are attached to the case to form a ceramic heater with heat radiation fins.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

As shown in a longitudinal cross-sectional view in FIG. 1, the ceramic heater with radiation fins of the present invention is constructed by using a plurality of ceramic heaters 1 and attaching a plurality of radiation fins 2 made of metal plates to these.

The ceramic heater 1 includes a heating resistor 1a in a ceramic body.
The heating resistor 1a is embedded therein and is provided with a lead wire 3 for supplying current to the heating resistor 1a. For example, a heating resistor 1a is produced by printing a heating pattern on a raw sheet of alumina ceramic with a paste made of Mo-Mn or -, and then overlaying raw sheets of alumina ceramic and sintering it in one piece. Just use it. In addition, silicon nitride,
It is also possible to use one in which the heating resistor 1a is embedded in a ceramic body such as aluminum nitride.

Furthermore, the heat dissipation fin 2 is a plate-shaped body made of metal such as aluminum, copper, or brass, and since these metals are light and have good thermal conductivity, they effectively transfer and dissipate the heat generated in the ceramic heater 1. Excellent hot air generation characteristics can be achieved. Aluminum in particular was excellent because it was protected by an oxide film on its surface and was resistant to deterioration.

Furthermore, a mounting hole 2a is formed in the radiation fin 2,
As shown in FIG. 2, the ceramic heater 1 with the metallized layer 1b formed thereon is inserted into the mounting hole 2a, and the ceramic heater 1 and the radiation fin 2 are fixed together by brazing. For brazing, Ag solder, Al solder, or a non-lambda solder such as PB-based, Zn-based, or Sn-based solder may be used. Further, as shown in FIG. 3, the metallized layer 1b of the ceramic heater 1 may be formed by dividing it in order to alleviate the difference in thermal expansion between the ceramic heater 1 and the metal fins 2 at high temperatures.

Furthermore, the mounting hole 2a of the radiation fin 2 is not completely punched out, but has a bent portion 2b, which allows the radiation fin 2 and the ceramic heater l to be firmly fixed. In addition, as shown in FIG. 1, the length of the bent portion 2b is
If the arrangement spacing is made to match the spacing between the radiating fins 2 and the radiating fins 2, it is easy to attach the heat dissipating fins 2.

In the above embodiment, only the ceramic heater 1 and the radiation fin 2 are fixed by brazing, but they may also be fixed by press fitting or adhesive.

Furthermore, the fixation of the ceramic heater 1 and the radiation fins 2 is not limited to brazing, and adhesives or the like may also be used.

Further, the three ceramic heaters 1 are connected in parallel, and the amount of heat generated can be adjusted by switching the energization to each ceramic heater 1. Further, the number of ceramic heaters 1 can be changed as necessary.

The device shown in this embodiment has a feature of good heat generation efficiency because the heat radiation fins 2 are directly attached to the ceramic heater 1.

Next, another embodiment of the present invention will be described.

As shown in Figures 4 and 5 (a) and (b),
The ceramic heater 1 is covered with metal cases 5a and 5b, and the radiation fins 2 made of metal plates similar to those in the above embodiment are attached to the cases 5a and 5b, and the ceramic heaters 1 are connected in parallel. be.

The metal cases 5a and 5b are made of the same metal material as the radiation fin 2, such as aluminum and copper, and as shown in FIG. 5(a), the ceramic heater 1 is covered with the cases 5a and 5b. Insert it into the mounting hole 2a of the rear heat dissipation fin 2 and attach it. At this time, the cases 5a, 5b and the radiation fins 2 may be fixed by brazing or simply by press fitting.

In addition, the ceramic heater 1 and the cases 5a, 5b are not fixed to each other, and the surface of the ceramic heater 1 is polished to have a smooth surface in order to improve mutual heat conduction, and the ceramic heater 1 and the cases 5a, 5b are It is sufficient if grease 6 is interposed between the two. As the grease 6, for example, silicone oil mixed with Al, Ni powder, etc. is used.

According to this embodiment, the ceramic heater 1 is placed in the case 5a.
, 5b, the ceramic heater 1 can be prevented from cracking, chipping, etc., and the radiation fins 2 can be easily attached by press-fitting.

As another embodiment, as shown in FIG. 6, the cases 5a and 5b are divided into a plurality of parts in the longitudinal direction of the ceramic heater 1, and each case 5a and 5b is brazed to the ceramic heater l. Each case 5a, 5b is fixed by
It is also possible to have heat dissipation fins 2 attached thereto. When the ceramic heater 1 and the metal cases 5a and 5b are brazed, the difference in thermal expansion at high temperatures becomes a problem.
By dividing 5b into a plurality of parts, the difference in thermal expansion can be alleviated.

In yet another embodiment, as shown in FIG. 7, the radiation fins 2 may be integrally formed in the cases 5a and 5b that cover the ceramic heater 1 in advance.

Furthermore, at least one of the plurality of ceramic heaters 1 constituting the ceramic heater with radiation fins shown in FIGS. 1 and 4 may be replaced with a PTC heater having a positive resistance temperature characteristic. If the PTC heaters are connected in series, the resistance value of the PTC heater increases rapidly at a certain temperature, so that the self-temperature control as a whole can be performed.

B. We prototyped a ceramic heater with radiation fins with the structure shown in Figure 4, and conducted various experiments. Ceramic heater 1
is made of alumina ceramics and has a thickness of 0.9 mm, a width of 10 mm, and a length of 97 mm.
, 5b are made of aluminum and have a thickness of 1 mm, and the heat dissipation fan 2 is made of aluminum, and 43 pieces having a thickness of 0.5 mm, a length of 66 mm, and 5 nm+m are used.

Regarding this ceramic heater with radiation fins, the surface of the ceramic heater 1 is polished and grease 6 is interposed between the ceramic heater 1 and the cases 5a and 5b (C
, ) and one in which the ceramic heater 1 was not polished and the grease 6 was not interposed (C2) were prepared. In addition, as a comparative example, a PTC heater made of barium titanate ceramics of exactly the same size was used (P).
prepared. For these three types, heater 1
When I investigated the relationship between the temperature ("C) and the output (-) of the 9th
It was as shown in the figure.

In Fig. 9, the comparative example P has an output of 1200-
I couldn't do more than that. On the other hand, C1 according to the embodiment of the present invention can be set to 1500- or more,
It was confirmed that the output was high. However, since C2 had poor heat dissipation characteristics, it was necessary to polish the surface of ceramic heater 1, and to
It can be seen that it is important to interpose grease between b.

Next, using the same ceramic heater with radiation fins as in Experimental Example 1, the surface of the ceramic heater 1 was polished, and the surface of the ceramic heater 1 was adjusted to 1200° without using Grease 6.

On the other hand, after 21.5 hours (184 cycles) (repeating the cycle of energizing on for 5 minutes and turning off for 12 minutes), changes in the output amount and heat generation temperature were investigated.The results are as shown in Table 1, with the initial value It was almost the same and had excellent durability.

Table 1 [Effects of the Invention] As described above, according to the present invention, a ceramic heater in which a heating resistor is embedded in a ceramic body is used, and a heat dissipation fin made of a plurality of metal plates is attached to the ceramic heater. By inserting the ceramic heater into a hole and fixing it, or by covering the ceramic heater with a metal case and attaching multiple metal radiating fins to the case to configure a ceramic heater with radiating fins, the heat of the ceramic heater can be transferred to the radiating fins. Since heat is efficiently dissipated through the ceramic heater and the ceramic heater itself can have a high output, it is possible to provide a ceramic heater with heat dissipation fins that has a large output and excellent heat generation characteristics.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view showing the overall structure of a ceramic heater with radiation fins according to an embodiment of the present invention, FIG. 2 is a partially exploded perspective view of the same, and FIG. 3 is a perspective view showing another example of the ceramic heater. . FIG. 4 is a longitudinal sectional view showing the overall structure of another embodiment of the present invention, FIG. 5(a) is a partially exploded perspective view, and FIG. 5(b)
is a sectional view taken along the line X--X in FIG. FIGS. 6 and 7 are longitudinal cross-sectional views showing still other embodiments of the present invention. FIG. 8 is a longitudinal sectional view showing a conventional PTC heater with radiation fins. FIG. 9 is a graph showing the relationship between the output and heat generation temperature of the ceramic heater with radiation fins according to the embodiment of the present invention.

Claims (2)

[Claims] (1) A ceramic heater with radiation fins, in which a ceramic heater having a heating resistor embedded in a ceramic body is inserted and fixed into a mounting hole formed in a radiation fin made of a plurality of metal plates. (2) A ceramic heater with radiation fins, characterized in that a ceramic heater having a heating resistor embedded in a ceramic body is covered with a metal case, and a plurality of metal radiation fins are attached to the case.