JP2692118B2 - Temperature control method for crucible type molten metal holding furnace - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a temperature control method for a crucible type molten metal holding furnace for maintaining a molten metal in a crucible in a desired state.

(Prior Art) A crucible type molten metal holding furnace is one in which a crucible made of metal or refractory is inserted into a furnace body and a heater is attached around the crucible so as to heat the crucible. To control the temperature of the molten metal in the crucible by heating the heater, a temperature sensor is attached so as to detect the heater temperature or the ambient temperature around the crucible, or a temperature sensor is installed in the molten metal. If the temperature sensor is in the molten metal, the heater may be overheated, so an upper limit circuit or the like is added. Another method is disclosed in
Japanese Patent Laid-Open No. 61-157643 proposes a method of controlling a heater at a predetermined temperature and cooling the molten metal when the molten metal temperature rises above a set value. The heater was operated intermittently based on the data from these temperature sensors, and the molten metal temperature in the crucible was maintained by PID control in which the derivative value and integrated value of the deviation were added in proportion to the deviation from the set value.

(Problems to be Solved by the Invention) However, the heater and the crucible are not in close contact with each other,
Since the heat of the heater intervenes air and the crucible, there is a time delay in the heat transfer. FIG. 6 illustrates the relationship between the temperature of the molten metal and the temperature of the heater chamber when the temperature sensor is provided in the molten metal. Points A and B are the points of temperature change when the molten metal is replenished or when the crucible lid is opened and oxides (Noro) are removed (disturbance). With respect to the temperature change at the point A, the heater is turned on and heated. Then, when the upper limit temperature Tah of the heater and the set molten metal temperature Tmo are reached, the heater is turned off, but the molten metal temperature rises due to the residual heat of the air and the crucible. After that, when the molten metal temperature naturally cools and falls below the set molten metal temperature Tmo, the heater is turned on, but since the temperature of the heater chamber is too low and the temperature is low, the molten metal temperature falls until it equilibrates with the heater chamber temperature. In this way, because air is present, in other words, the temperature sensor and the heat source are far apart, so the response of the temperature control of the molten metal is poor,
Moreover, if the molten metal is naturally cooled and lowered to the set temperature, the temperature of the heater chamber will drop too much. The same can be said at point B. However, the means of the above publication consumes much energy.

An object of the present invention is to provide a temperature control method for a crucible-type molten metal holding furnace which can control the temperature of the molten metal with a smaller deviation from a set value.

(Means for Solving the Problem) In order to achieve the above-mentioned object, the present invention sets an upper and lower limit temperature that is allowed with respect to a set temperature of the molten metal, and a heater chamber for heating a crucible filled with the molten metal. The upper and lower limits of the heater chamber temperature are set in stages, the heater chamber temperature is controlled within the upper and lower limits by the amount of deviation between the molten metal temperature and the set temperature, and the upper and lower limit temperatures at which the detected molten metal temperature is allowed When the time is not in between, the heater chamber is forcibly heated or cooled with the upper limit or the lower limit of the temperature of the heater chamber as a target.

Further, in the above configuration, the upper and lower limit temperatures allowed with respect to the set temperature of the molten metal are set in stages, and the upper and lower limit ranges of the heater chamber temperature are changed and controlled depending on the deviation amount between the molten metal temperature and the set temperature. It is characterized by doing so.

(Operation) With this configuration, the molten metal temperature is within the set upper and lower limits, and the heater chamber temperature due to heating the heater (heat source) is within the upper and lower limits. In some cases, the temperature of the molten metal is maintained by determining whether the temperature is higher or lower than the set value by the detection signal of the molten metal temperature, and controlling the heater by the calculation signal of the deviation amount (temperature increase or lower limit).

When the molten metal temperature is out of the upper and lower limits, the heat source is forcibly activated or stopped. In this case, the heat source is operated or stopped with the upper limit or the lower limit of the heater chamber temperature as a target in consideration of the temperature responsiveness.

When the melt temperature increases or decreases sharply, it is determined whether the melt temperature is high or low and whether it is rising or falling, and the heat source is turned on or off with the maximum or minimum heater chamber temperature as the target. To

During the above operation of the heater chamber temperature, when the heater chamber temperature reaches the upper limit or the lower limit, it is maintained, and when the molten metal temperature reaches the upper limit or the lower limit, the heat source is stopped or activated. By this operation, the molten metal temperature approaches the set value, and the upper and lower limit range of the heater chamber temperature is gradually narrowed to maintain the molten metal temperature at the set value.

(Example) An example of the method of the present invention will be described with reference to FIGS. 1 to 4.

 FIG. 1 shows an apparatus for carrying out the method of the present invention.

This device is composed of a control device in which a temperature sensor is arranged in the holding furnace and the heater is controlled by this temperature detection signal. In the figure, a holding furnace 1 is one in which a crucible 2 made of metal or refractory is inserted into a heater chamber 4 having an upper opening provided in a furnace body 3. The crucible 2 is filled with the molten metal 5, and the furnace lid 6
Sealed. A flange portion 2a formed on the edge of the crucible 2 supports the crucible 2 from the furnace body 3 and seals the heater chamber 4.

The thermocouple 8 covered with the protective tube 7 is immersed in the molten metal 5,
It is fitted in and supported by the furnace lid 6. And the heater chamber 4
A protective tube 9 penetrating from the side wall of the furnace body 3 is projectingly provided in the tube, and a thermocouple 10 is inserted into the protective tube 9. A heater 11 for heating the crucible 2 is arranged on the peripheral wall in the heater chamber 4 of the furnace body 3, and is connected to a final stage element of a control circuit 12 for adjusting the output of the heater, for example, a thyristor 13.

The thermocouple 8 is connected to the control circuit 12 through the molten metal temperature controller 14. Similarly, the thermocouple 10 is also the heater room temperature controller.
It is connected to the control circuit 12 by relaying 15.

The molten metal temperature controller 14 receives the detection signal of the thermocouple 18 and outputs a PID signal calculated from the deviation amount from the molten metal temperature set value Tmo and its change speed, which is the allowable value of the set value Tmo. When the upper limit temperature Tmh and the lower limit temperature Tml are excluded, a molten metal upper limit signal and a molten metal lower limit signal are output, respectively.

The heater chamber temperature controller 15 receives the detection signal of the thermocouple 10 and determines the heating temperature range by setting the lower limit temperatures tal ₁ , tal ₂ (tal ₁
When <tal ₂ ) or the upper limit temperatures tah ₁ and tah ₂ (tah ₁ > tah ₂ ) are exceeded, the respective signals are output.

Here, how to obtain the upper limit temperatures tah ₁ and tah ₂ and the lower limit temperatures tal ₁ and tal ₂ of the heater chamber temperature will be described.

The upper limit temperature tah ₁ and the lower limit temperature tal ₁ of the heater chamber temperature ta are
When affected by a relatively large disturbance expected in this control system, the melt temperature Tm is quickly recovered and is appropriately set within a range that does not significantly overshoot the melt temperature set value Tmo. Also, the upper limit temperature ta of the heater chamber temperature ta
The h ₂ and the lower limit temperature tal ₂ are the temperature range of the heater chamber where the balance of heat is balanced when there is no large disturbance. In this way, the upper and lower limit temperatures of the heater chamber are set in stages.
Since this equilibrium temperature is affected by the amount of molten metal 5 and changes in the thermal conductivity of the crucible 2, its maximum temperature is tah ₂ and the minimum temperature ta.
l ₂ .

For the upper limit temperature Tmh of the melt temperature Tm, the melt temperature Tm is the set value Tmo.
, And the and the heater chamber temperature ta is the upper limit temperature tah ₂ Noto, set within a range in which the melt temperature Tm does not exceed this in the middle of the heater output is decreasing. Similarly for the lower limit temperature Tml, the melting temperature T
m is the set value Tmo, and the heater chamber temperature ta is the lower limit temperature ta.
When the value is l ₂ , the molten metal temperature Tm is set within the range of not falling below the lower limit temperature Tml while the heater output is increasing.

Specifically, as an example, when the molten aluminum is put in a graphite crucible 1t container, when the molten metal temperature set value Tmo is 700 ° C, the upper limit temperature Tmh is 705 ° C, and the lower limit temperature Tml is 695 ° C,
Set the lower limit temperature tal ₁ and tal ₂ to 680 ° C, 7
20 ° C., the upper limit temperatures tah ₁ and tah ₂ were 800 ° C. and 740 ° C.

Next, the method of the present invention performed on the basis of the temperature thus determined will be described with reference to the flowchart of FIG.

First, the molten metal temperature Tm is detected to determine whether it is within an allowable value (steps 1, 2, 3). Next, it is determined whether the heater chamber temperature ta is within the upper limit temperature tah ₂ and the lower limit temperature tal ₂ (steps 4 and 5), and when these conditions are satisfied, PID control (step 6) is performed. Further, when the molten metal temperature Tm is out of the allowable value, if the heater chamber temperature ta is higher than the upper limit temperature tah ₁ , the heater is forcibly stopped (steps 7 and 8), and the heater chamber temperature ta is set to the lower limit temperature tal _1. If it is lower than this, the heater is forcibly activated (steps 9 and 10).
Control PID. Even if the melt temperature Tm is within the allowable range,
When the heater chamber temperature ta is higher than the upper limit temperature tah ₂ , the heater is stopped (steps 4, 8), and when it is lower than the lower limit temperature tal ₂ , the heater is operated (steps 5, 10).

The operating state of the heater thus controlled is divided into three sections, A, B, and C, as shown in FIG. 3, in which area A is forcibly inserted and area B is used for PID control of the heater. The area C is forcibly turned off.

Next, referring to FIG. 4, when the molten metal temperature Tm suddenly drops from the equilibrium state (point A), even if the molten metal temperature Tm is rising or falling, the deviation amount of the molten metal temperature Tm and its changing speed, etc. By the calculated PID signal, the heater chamber temperature ta is heated so as to rise. Then, when the upper limit temperature tah ₁ in the range of the heater chamber temperature ta is reached, the heater chamber temperature ta is controlled to be constant until the molten metal temperature Tm reaches the lower limit temperature tml in the allowable range, and the upper limit temperature tah ₁ set stepwise is set. It cannot be exceeded. After that, the upper limit temperature ta in the narrow range of the heater chamber temperature
The molten metal temperature Tm is PID controlled within the h ₂ and lower limit temperature tal ₂ . Also, when the melt temperature Tm rapidly rises, PID control is performed in the same manner.

FIG. 5 shows the distribution of PID control according to another embodiment. In this method, the allowable value of the molten metal temperature Tm is divided into two stages, and the control range of the heater chamber temperature is divided into three stages. Therefore, the molten metal temperature Tm can be controlled more finely, and the amplitude can be efficiently reduced with respect to disturbance. Can be converged to the waveform of.

(Effect of the Invention) The method of the present invention sets the upper limit and the lower limit of the temperature of the molten metal as described above, and sets the upper limit and the lower limit of the heater chamber temperature stepwise. The molten metal temperature can be maintained close to the set temperature by the PID signal calculated from the deviation amount of the molten metal temperature from the set temperature and the changing speed thereof. Moreover, since the upper and lower limits of the heater chamber temperature are set, the heater chamber temperature is not heated or cooled more than necessary with respect to the deviation amount of the molten metal temperature. For this reason, since the lower limit of the heater chamber temperature is determined against the rapid temperature rise of the molten metal, the molten metal will not be overcooled. Further, when the temperature of the heater chamber is increased, the upper limit temperature is set, so that the heating temperature is lower than in the conventional case, the amount of heat loss is reduced, and therefore the molten metal holding energy can be reduced.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a temperature control device for carrying out the method of the present invention, FIG. 2 is a flow chart showing the method of the present invention, and FIG. 3 is a range of molten metal temperature for showing the temperature control according to the method of the present invention And FIG. 4 is a diagram showing the relationship between the temperature range of the heater chamber and FIG. 4, FIG. 4 is a diagram showing the operating characteristics of the temperature control of this device, and FIG. And FIG. 6 is a diagram showing the relationship between the heater chamber temperature range and FIG. 6 is a diagram showing operating characteristics of conventional temperature control. Tm: Molten metal temperature, Tmo: Molten metal temperature set value ta: Heater chamber temperature

Claims (2)

(57) [Claims] 1. An upper and lower limit temperature allowable for a set temperature of the molten metal is set, and an upper limit and a lower limit of a heater chamber temperature of a heater chamber for heating a crucible filled with the molten metal are set in stages to obtain the molten metal temperature. And the set temperature, the heater chamber temperature is controlled within the upper or lower limit range, and if the detected molten metal temperature is not between the allowable upper and lower limit temperatures, the heater chamber temperature is forced to the upper or lower limit. A temperature control method for a crucible-type molten metal holding furnace, wherein the heater chamber is heated or cooled with a lower limit as a target. 2. The upper and lower limit temperatures allowed with respect to the set temperature of the molten metal are set in stages, and the upper and lower limits of the heater chamber temperature are changed and controlled according to the deviation amount between the molten metal temperature and the set temperature. The temperature control method for the crucible type molten metal holding furnace according to claim 1, wherein the method is as described above.