JPH03158696A - Kiln - Google Patents

Abstract

PURPOSE:To provide a fired product of constant quality through prevention of the occurrence of a fluctuation in oxygen concentration and elimination of an influence exercised by exhaust gas by a method wherein by using a combustion heat source used for the interior of a furnace chamber forming a combustion chamber, the combustion chamber is partitioned away from a firing chamber by means of a partition wall to control atmosphere in the burning chamber. CONSTITUTION:A partition wall 6 by which a combustion chamber 4 and a firing chamber 5 are partitioned away from each other is formed in a tunnel shape by using a refractory material and arranged on a fire-resisting support member 8. A burner 7 is a combustion heat source, e.g. gas burner, oil burner, and arranged so that it performs combustion in a combustion chamber 4 set in a furnace chamber 2. As noted above, a combustion heat source 7 is used as a heat source to heat the furnace chamber 2, and the combustion chamber 4 and the firing chamber 5 for which the combustion heat source 7 is used are partitioned away from each other by the partition wall 6 to control atmosphere. Therefore, even when combustion operation of the combustion heat source 7 is fluctuated, interference with oxygen concentration in the firing chamber 5 is prevented from occurring. Further, it is preferable that gas in the combustion chamber 4 and gas in the firing chamber 5 are discharged through discharge passages 10 and 11 through different systems.

Description

Detailed Description of the Invention <Industrial Application Field> The present invention relates to a firing furnace used for firing ceramic products, in which a combustion heat source is used as the furnace chamber heating source, and the combustion chamber and the firing chamber are separated by a partition wall. By doing so, it is possible to prevent interference caused by the combustion operation of the combustion heat source, to obtain a fired product of constant quality, and to reduce thermal energy costs.

<Prior Art> Ceramics used in various electronic components and the like are obtained by firing a molded product of a mixture of a predetermined porcelain powder and an organic binder in a firing furnace. A firing chamber is provided in the furnace chamber of the firing furnace, and the article to be fired is fired under preset time and temperature conditions when passing through the firing chamber. As a heating method for the furnace chamber, a heating method that directly heats the furnace chamber using an electric heat source or a combustion heat source such as a burner is generally used.

<Problems to be Solved by the Invention> However, when an electric heat source is used as a heat source for the furnace chamber, the cost of thermal energy increases, leading to an increase in the cost of the product.

On the other hand, when using a combustion heat source, the thermal energy cost is lower than when using an electric heat source, but the product to be fired is subject to interference from the combustion operation of the combustion heat source, which tends to cause characteristic fluctuations. This problem is particularly likely to occur when a combustion heat source is used as a heat source.For example, when the temperature inside the furnace chamber is raised, the oxygen consumption of the combustion heat source increases, and when the temperature is lowered, the oxygen consumption decreases. . As mentioned above, ceramics contain an organic binder, and the organic binder is burned in a firing furnace. However, since the oxygen consumption in the furnace chamber varies depending on the temperature rise or fall of the combustion heat source, the combustion of the organic binder is also affected by the oxygen consumption of the combustion heat source, which has negative effects such as reduction of the ceramic product.

In addition, in the case of a direct heating method using a combustion heat source, it is possible to avoid the influence of combustion gas on the fired product, but uneven removal of the binder occurs, which tends to cause quality defects such as cracks in the product.

In order to avoid this problem, conventionally, an electric heat source has been used in the preheating zone instead of a combustion heat source. For this reason, an increase in cost was unavoidable.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to solve the above-mentioned conventional problems, prevent product interference due to the combustion operation of a combustion heat source, make it possible to obtain baked products of constant quality, and reduce thermal energy costs. The purpose of the present invention is to provide a firing furnace.

Means for Solving the Problems> In order to solve the above-mentioned problems, the present invention provides a firing furnace having a firing chamber inside the furnace chamber, wherein the furnace chamber is used as a combustion chamber as a heat source for heating the furnace chamber. The method is characterized in that a combustion heat source is used, the combustion chamber and the firing chamber are separated from each other by a partition wall, and the atmosphere inside the firing chamber is controlled.

Effect> Since a combustion heat source with a combustion chamber inside the furnace chamber is used as a heat source for heating the furnace chamber, the cost of thermal energy becomes low.

Moreover, the combustion chamber of the combustion heat source and the firing chamber are separated from each other by a partition wall, making it possible to control the atmosphere inside the firing chamber, thereby preventing product interference due to the combustion operation of the combustion heat source.
For example, a fired product of constant quality can be obtained by blocking the effects of oxygen concentration fluctuations and exhaust gas.

<Example> FIG. 1 is a sectional view of a firing furnace according to the present invention, and FIG. 2 is a sectional view taken along line A and -A in FIG. 1.

1 is a fireproof outer wall, 2 is a furnace chamber, 3 is a product to be fired, 4 is a combustion chamber,
5 is a firing chamber, 6 is a partition wall, and 7 is a combustor. Fireproof outer wall 1
is formed into a tunnel shape using refractory bricks, etc. The furnace chamber 2 is surrounded by a refractory outer wall 1, and inside the furnace chamber 2, fireproof support members 8 in the form of railroad ties are arranged at appropriate intervals from the bottom. A large number of refractory support members 8 are arranged at regular intervals along the length direction of the furnace chamber 2, and a rail-shaped refractory support member 9 is placed above them along the length direction of the furnace chamber 2. It is located.

The product to be fired 3 is a ceramic product containing an organic binder placed inside a heat-resistant case, and is usually placed on a heat-resistant base plate and placed along the firing chamber 5 as indicated by arrow a ( 342) direction) continuously or intermittently.

The atmosphere in the firing chamber 5 is controlled to contain 1 fil of carbon dioxide, carbon monoxide, water vapor, or hydrocarbon gas, depending on the product 3 to be fired. Also, its concentration etc. are controlled.

The partition wall 6 separates the combustion chamber 4 and the firing chamber 5 from each other. This partition wall 6 is constructed in the shape of a tunnel using a refractory material, and is arranged on a refractory support member 8 .

The combustor 7 is a combustion heat source such as a gas burner or an oil burner, and is arranged so that combustion occurs in a combustion chamber 4 set within the furnace chamber 2 . 71 indicates the flame. In the embodiment, the combustor 7 is introduced into the combustion chamber 4 in the furnace chamber 2 from the outside at the upper and lower parts of the refractory outer wall 1 . The number of combustion I17 is arbitrary.

As mentioned above, since the combustion heat source 7 is used as the heat source for heating the furnace chamber 2, the thermal energy cost is low.For example, the thermal energy cost of the electric heat source is 18.6 yen/c.
al, the thermal energy cost of combustion heat sources using kerosene, A heavy oil, and liquefied gas is 2.49 yen/each.
Cal, 2. 48 yen/Kcal, 2.61 yen/cal, significantly reducing thermal energy costs.

Moreover, the combustion chamber 4 and the firing chamber 5 of the combustion heat source 7 are separated by a partition wall 6.
Since the two chambers are separated from each other and the atmosphere thereof is controlled, even if the combustion operation of the combustion heat source 7 fluctuates, there will be no interference, particularly with respect to the oxygen concentration within the firing chamber 5.

Further, since indirect heating is performed via the partition wall 6, the binder is removed evenly and quality defects such as cracks are reduced.

As shown in FIG. 2, the combustion chamber 4 and the firing chamber 5 are desirably exhausted through separate exhaust channels 10, 11, respectively. The present invention is suitable for application to heating in a preheating zone, but can also be applied to heating in a high temperature zone or a cooling zone.

<Effects of the Invention> As described above, according to the present invention, the following effects can be obtained.

(a) Since a combustion heat source is used as a heat source for heating the furnace chamber, a firing furnace with low thermal energy cost can be provided.

(b) The combustion chamber of the combustion heat source and the firing chamber are separated from each other by a partition wall, and the atmosphere inside the firing chamber is controlled, preventing product interference due to the combustion operation of the combustion heat source and producing fired products of constant quality. is obtained.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a firing furnace according to the present invention, and FIG. 2 is a partial sectional view taken along line A, -A in FIG. 2... Furnace chamber 3... Product to be fired 4... Combustion chamber 5... Firing chamber 6... Partition wall
7... Combustion heat source Figure 1 Figure 2 A,,a

Claims (2)

[Claims] (1) A firing furnace having a firing chamber inside the furnace chamber, wherein a combustion heat source with a combustion chamber inside the furnace chamber is used as a heat source for heating the furnace chamber, and the combustion chamber and the firing chamber are separated from each other by a partition wall. A firing furnace characterized in that the firing chamber is divided into sections and the atmosphere inside the firing chamber is controlled. (2) The atmosphere in the firing chamber includes carbon dioxide gas, carbon monoxide,
The kiln according to claim 1, characterized in that the kiln contains one of water vapor and hydrocarbon gas.