KR20230093703A - Thermostatic oven for heat treating apparatus - Google Patents

Abstract

In the present invention, the end of the cooling water pipe supplying the cooling water to the constant temperature furnace body is supplied under the stirring blades installed in the constant temperature furnace body, but as the stirring blades rotate, the cooling water supplied by the rotational force flows inside the constant temperature furnace body. Its purpose is to provide a constant temperature furnace for heat treatment that allows heat exchange to be performed evenly and to be used safely and conveniently without the risk of explosion and to increase rapid cooling and constant temperature effects. In addition, when there are several stirring blades, the present invention configures the cooling water to be supplied from one of the mutually adjacent stirring blades, so that the cooling water is evenly mixed in the constant temperature furnace body using the rotational force of the stirring blades, thereby delaying rapid heat exchange Another object is to provide a constant temperature furnace for heat treatment that can be used safely and conveniently.

Description

Thermostatic furnace for heat treatment {THERMOSTATIC OVEN FOR HEAT TREATING APPARATUS}

The present invention relates to a constant-temperature furnace for heat treatment, and more particularly, by configuring the cooling water supplied under the stirring blades to quench or maintain an isothermal state of an object transferred to the constant temperature furnace body after heat treatment, so that the cooling water is supplied through the stirring blades. As it collides with the bottom of the constant temperature furnace body, the circulation of the golgo furnace is evenly and quickly performed in the constant temperature furnace body, so that explosion accidents that may occur inside the constant temperature furnace body can be prevented in advance, while rapid cooling or isothermal efficiency can be increased.

In general, in heat treatment, an object heat-treated at a set temperature and time in a heat treatment furnace is moved to a constant temperature furnace, and the object is rapidly cooled by water or oil cooling in the constant temperature furnace, or isothermally transformed by maintaining a constant temperature in a salt bath to obtain a heat treatment effect. In the following (Patent Document 1) to (Patent Document 3), a heat treatment technique including a heating furnace for forming an oxide film and a constant temperature furnace for rapid cooling or isothermal treatment of an object heat-treated in the heating furnace is disclosed.

(Patent Document 1) Korea Patent Registration No. 10-0339848

It relates to a heat treatment facility for austemper nodular cast iron capable of producing high-quality austemper nodular cast iron at low cost. Its configuration is that in a normal austempering heat treatment facility, a non-oxidation line into which fuel such as LPG, LNG, and alcohol is injected is connected to the inside, and the injected fuel is ignited by the internal temperature to burn oxygen and oxidize the surface of the heat treatment object. A heating furnace capable of preventing the formation of a film, a heating medium circulator having a plurality of wings circulating a heater, a cooling pipe cooling the heating medium, and a heating medium circulating the heating medium, which are made in the shape of an oval and have a heating medium on one side of the inside, respectively. There is provided a heat treatment facility for austemper spheroidal graphite cast iron, characterized in that it comprises a constant temperature furnace installed to be immersed so that rapid cooling or isothermal maintenance is achieved, and a washing tank spaced apart from one side of the constant temperature furnace.

Korean Patent Registration No. 10-0339848 (registration date: 2002.05.24)

However, the constant temperature furnace used in such an existing heat treatment facility has the following problems.

(1) When cooling water is supplied to the inside of the constant temperature furnace for the purpose of rapid cooling, the temperature inside the constant temperature furnace is high and the cooling water supplied to the constant temperature furnace vaporizes. The rate of evaporation of the cooling water increases as the internal temperature of the constant temperature furnace increases.

(2) And this phenomenon is dangerous because the temperature inside the constant temperature furnace rises and there is a possibility that the constant temperature furnace may explode.

(3) In particular, cooling water used for rapid cooling or the like adds ingredients such as sodium to the cooling water to increase the cooling effect, and because of these additional ingredients, the cooling water supplied to the constant temperature furnace is more likely to explode during heat exchange.

(4) In addition, due to such a rapid phase change inside the constant temperature furnace, heat exchange between the cooling water supplied to the constant temperature furnace and the heat-treated object is not sufficiently performed, and rapid cooling or constant temperature effect may be deteriorated.

(5) In addition, the cooling water supplied through the top of the stirring blades of the constant temperature furnace stirrer is not evenly circulated throughout the inside of the constant temperature furnace, so there is a limit to this rapid cooling or constant temperature effect in part. This may cause partial rapid cooling or constant temperature treatment not to be performed properly when rapidly cooling or constant temperature treatment of the heat-treated object.

The present invention takes this point into consideration, and the end of the cooling water pipe supplying the cooling water to the constant temperature furnace body is supplied under the stirring blades installed in the constant temperature furnace body, and the cooling water supplied by the rotational force as the stirring blades rotate. It is an object of the present invention to provide a constant temperature furnace for heat treatment in which heat exchange is performed well by spreading evenly inside the constant temperature furnace main body, and it is possible to use it safely and conveniently without the risk of explosion and to enhance rapid cooling and constant temperature effects.

In addition, the present invention is configured so that the cooling water is supplied under the stirring blades installed on the top when there are several stirring blades, so that the cooling water is evenly mixed in the constant temperature furnace body using the rotational force of the stirring blades, so that rapid heat exchange is delayed and safe. Another object is to provide a constant temperature furnace for heat treatment that can be conveniently used.

In order to achieve this object, the constant temperature furnace for heat treatment according to the present invention has an inlet 110 formed at the top, an openable door 111 is provided at the inlet 110, and a constant temperature furnace main body 100 made of a refractory material; an actuator 200 installed outside the constant temperature furnace main body 100 to open and close the door 111; at least one heater 300 installed on the constant temperature furnace main body 100 and having one side exposed in the constant temperature furnace main body 100 to adjust the internal temperature; and at least one agitation vane 410 installed on a shaft rotating in place with one side exposed inside the constant temperature furnace body 100 and the other side exposed outside the constant temperature furnace body 100, and the outside of the constant temperature furnace body 100. A stirring means 400 including an actuator 420 installed on the stirring blade 410 forcibly rotating; A cooling water pipe 500 for supplying cooling water from the outside is installed in the constant temperature furnace main body 100, and the cooling water pipe 500 supplies cooling water under the stirring blades 410 so as to generate rotational force of the stirring blades 410. It is characterized in that the cooling water is supplied so that the cooling water is evenly spread in the constant temperature furnace main body 100.

In particular, in the constant temperature furnace body 100, the inner surface 100' is finished with SUS 304 having a thickness of 3 mm to 20 mm and the outer surface 100" is finished with a general iron plate having a thickness of 4.5 mm to 20 mm. to be characterized

In addition, one side of the door 111 is rotatably mounted on the constant temperature furnace main body 100 using a hinge, and the actuator 200 rotates in place on one side outside the constant temperature furnace main body 100. It is characterized in that the cylinder is installed and the other side is rotatably installed on the door 111.

Finally, the cooling water pipe 500 is configured to supply cooling water between the two stirring blades 410 when there are two stirring blades 410, and when there are several stirring blades 410, adjacent to each other. It is characterized in that the cooling water is installed to be supplied to any one of the stirring blades 410.

The constant temperature furnace for heat treatment according to the present invention has the following effects.

(1) The cooling water supplied through the cooling water pipe is configured to be distributed under the stirring blades by the rotation of the stirring blades, so that the cooling water is evenly distributed inside the constant temperature furnace to increase rapid cooling and isothermal effects.

(2) In particular, the newly supplied cooling water spreads quickly and widely inside the constant temperature furnace, so that the temperature of the cooling water filled inside the constant temperature furnace is maintained uniformly and partially rapidly through the effect of delaying heat exchange without rapid rise can be prevented.

(3) Therefore, it is possible to prevent a phenomenon in which the temperature of the cooling water is partially different during rapid cooling, etc., so that the rapid cooling or constant temperature effect on the surface of the heat treatment object is different, and the cooling water rapidly expands, causing an explosion that may occur inside the constant temperature furnace. Accidents can be prevented in advance.

(4) On the other hand, when there are two stirring blades, cooling water is supplied between them, and when several stirring blades are configured, cooling water is supplied under the top stirring blade, so that the cooling water passes through several stirring blades at a constant temperature. By spreading evenly inside the furnace, it is possible to further enhance the quenching effect and constant temperature effect.

[Figure 1] is a front view schematically showing the overall configuration of a constant temperature furnace for heat treatment according to the present invention.
[Fig. 2] is a side cross-sectional view showing the entire configuration of a constant temperature furnace for heat treatment according to the present invention.
[Fig. 3] is a front cross-sectional view showing the entire configuration of a constant temperature furnace for heat treatment according to the present invention.
[Figure 4] is a cross-sectional plan view showing the overall configuration of a constant temperature furnace for heat treatment according to the present invention.
[Figure 5] is a side view showing a coupling structure between a door and an actuator according to the present invention.
[Figure 6] is a front cross-sectional view of a constant temperature furnace for heat treatment showing a state in which cooling water is supplied through a cooling water pipe according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors should properly define the concept of terms in order to best explain their invention. According to the principle that it can be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, various equivalents that can replace them at the time of this application It should be understood that there may be variations.

[for heat treatment of constant temperature furnace composition]

In the constant temperature furnace for heat treatment according to the present invention, as shown in [Figs. A pipe 500 is included.

In particular, the cooling water pipe 500 is configured to supply the cooling water under the stirring blades 410 of the stirring means 400 when the cooling water is supplied into the constant temperature furnace main body 100, so that the cooling water is supplied as the stirring blades 410 rotate. While hitting the bottom of the constant temperature furnace 100, it spreads evenly inside the constant temperature furnace 100 so that the quenching effect and the constant temperature effect can be enhanced.

At this time, when the cooling water pipe 500 has two stirring blades 410, the cooling water is supplied between the two, and when there are several stirring blades 410, any of the adjacent stirring blades 410 is provided. By configuring the cooling water to be supplied to one unit, the cooling water is spread more widely and evenly using the rotation of the agitation blades 410 that rotate sequentially, so that rapid cooling and constant temperature effects can be enhanced.

Hereinafter, this configuration will be described in more detail with reference to the accompanying drawings. Here, 'cooling water' is water for quenching the heat-treated object, and may be general water or water with additives such as salt added to the water.

go. constant temperature furnace main body

As shown in [FIGS. 1] to [FIG. 4], the constant temperature furnace main body 100 accommodates the heat treatment object that has been heat treated in the heat treatment furnace therein and maintains a constant temperature therein to increase the constant temperature effect, or coolant therein It is a furnace for use when quenching an object to be heat treated by injecting. The constant temperature furnace main body 100 is shown in the drawing as being manufactured in the form of a track of a stadium. In addition, the constant temperature furnace main body 100 is preferably made of a heat insulating material so as to withstand sufficient heat for rapid cooling and constant temperature maintenance.

The constant temperature furnace main body 100 includes an inner surface 100', an outer surface 100", and an inlet 110 as shown in [FIG. 1] to [FIG. 4].

1. Inner and outer

The inner surface 100' and the outer surface 100", as shown in [FIG. 2] to [FIG. 4], are designed to reinforce the inside and outside of the constant temperature furnace main body 100 made of refractory material so as to be sufficiently resistant to rigidity and heat. The inner surface (100') is preferably finished with SUS 304 having a thickness of 3 mm to 20 mm, and the outer surface (100") is preferably finished with a general iron plate with a thickness of 4.5 mm to 20 mm.

2. Entrance

The inlet 110 is formed above the constant temperature furnace main body 100 as shown in FIG. 2 . This inlet 110 allows the object to be heat treated in the heat treatment furnace to be put into or taken out of the constant temperature furnace main body 100 . Therefore, the inlet 110 may be formed on the side of the constant temperature furnace main body 100, but in general, cooling water or the like is injected into the constant temperature furnace main body 100 to perform rapid cooling and constant temperature treatment, so that the cooling water or the like is prevented from leaking It is preferable to configure on the constant temperature furnace main body 100 so as to be able to do so.

On the other hand, in the inlet 110, as shown in [FIG. 1], [FIG. 2], [FIG. 4] and [FIG. 5], the constant temperature furnace body 100 is safe and prevents heat loss and has rapid cooling and constant temperature maintenance effects. A door 111 is provided so as to be elevated. At this time, the door 111 is opened and closed by an actuator 200, which will be described later. It is configured to be separated from the constant temperature furnace body 100 through the actuator 200 or configured to be rotated using a hinge, etc., Any structure can be configured as long as the inlet 110 can be opened and closed so that an object to be heat treated can be inserted into the main body 100 of the constant temperature furnace or an object to be subjected to heat treatment can be taken out after rapid cooling or constant temperature treatment. Therefore, it is preferable to have a seal on the constant temperature furnace main body 100 that comes into contact with the door 111 when it is closed so as to partition the inside and outside of the constant temperature furnace main body 100 so that rapid cooling or a constant temperature state can be achieved.

me. actuator

The actuator 200 is mounted on the side of the constant temperature furnace main body 100 so that the above-described door 111 can open and close the inlet 110, as shown in [FIGS. 1], [FIG. 4] and [FIG. 5]. . At this time, as the actuator 200, any structure capable of opening and closing the door 111 in the constant temperature furnace main body 100 may be used. For example, by using a cylinder, the door 111 is lifted separately from the constant temperature furnace body 100, or the door 111 rotatably installed on the constant temperature furnace body 100 with a hinge or the like is rotated to open and close. can be configured. At this time, it is preferable to configure the cylinder to rotate together so as to eliminate rotational interference that may occur while the door 111 is opened and closed. In addition to this, the door 111 may be directly opened and closed by using a rack-pinion or by directly mounting a motor on the shaft of the door 111 .

all. heater

The heater 300, as shown in [FIG. 1] and [FIG. 2], maintains the temperature inside the constant temperature furnace main body 100 constant and provides sufficient heat so that the constant temperature effect can be achieved. At this time, as the heater 300, any heater may be used as long as it can raise or lower the temperature inside the constant temperature furnace main body 100 to a desired temperature, such as using a heat medium or electric power. Therefore, it is preferable that the heater 300 detects the temperature inside the constant temperature furnace main body 100 and blinks the operation of the heater 300 based on the detected temperature.

As shown in [FIG. 1] and [FIG. 2], one side of the heater 300 is exposed to the constant temperature furnace body 100 so that heat transfer can be ensured, and the temperature inside the constant temperature furnace body 100 is increased. It is preferable to install at least one so as to sufficiently maintain, and the drawing shows that four are mounted as an example.

la. stirring means

As shown in [Figs. 2] to [Fig. 4], the stirring unit 400 is installed in the constant temperature furnace body 100 and operates when the heater 300 operates or cooling water to be described later is supplied, so that the constant temperature furnace body (100) It is possible to increase the constant temperature effect and rapid cooling effect by maintaining the internal temperature constant.

The stirring means 400 includes a shaft 430, at least one stirring blade 410, and an actuator 420, as shown in FIGS. 2 to 4.

1. axis

The shaft 430 is installed on the upper part of the constant temperature furnace main body 100, and one side is inserted into the constant temperature furnace main body 100 and supported by the constant temperature furnace main body 100 so that it can rotate in place. At this time, it is preferable that the shaft 430 is configured to be rotated in place through an actuator 420 to be described later while being sealed so that gas generated in the constant temperature furnace body 100 is not exposed to the outside.

In a preferred embodiment of the present invention, the shaft 430 is mounted at a position biased to one side of the constant temperature furnace main body 100, so that when the agitation means 400 operates, the heat treatment object put into the constant temperature furnace main body 100 and It is desirable to configure it so that it does not touch or interfere.

2. stirring wing

The stirring blades 410 are mounted on the shaft 430 installed penetrating the above-described constant temperature furnace main body 100, as shown in [FIG. 2] and [FIG. 3]. At this time, at least one stirring blade 410 is installed, and as the shaft 430 rotates, the cooling water supplied through the inside of the constant temperature furnace main body 100 or through the cooling water pipe 500 to be described later is transferred to the constant temperature furnace main body 100. ) and evenly distributed in it.

In a preferred embodiment of the present invention, as shown in [Fig. 6], several stirring blades 410 may be installed on a shaft inserted into the constant temperature furnace main body 100, and among them, they are installed so as to be positioned at least on top. It is preferable that the stirring blades 410 are mounted so that fluid flows toward the bottom of the constant temperature furnace body 100 . This allows the cooling water supplied through the cooling water pipe 500 to be described later to be supplied under the agitation vanes 410, so that the cooling water flows toward the bottom of the constant temperature furnace body 100 and spreads widely while spreading throughout the constant temperature furnace body 100. This is to ensure that heat exchange is not abruptly performed by spreading evenly and that a delaying effect can be obtained. This is because the salt bath already supplied to the constant temperature furnace main body 100 and the newly introduced cooling water are evenly mixed, thereby preventing a rapid partial rise in temperature or the concentration of relatively low temperature cooling water to one side, thereby reducing the constant temperature furnace main body 100. As the cooling water supplied to the system gradually changes in temperature as a whole, stable temperature changes can be obtained, and rapid cooling and constant temperature effects can be enhanced.

mind. coolant pipe

As shown in [Figs. 3] and [Fig. 6], the cooling water pipe 500 supplies cooling water from outside the constant temperature furnace main body 100 into the constant temperature furnace main body 100 to the object to be subjected to heat treatment put into the constant temperature furnace main body 100. It is possible to obtain rapid cooling or constant temperature effect.

At this time, the cooling water pipe 500 is configured so that the cooling water supplied into the constant temperature furnace main body 100 is ejected from under the stirring blades 410, as shown in [FIG. 3] and [FIG. 6], so that the stirring blades ( 410) to evenly mix the cooling water supplied into the constant temperature furnace main body 100 in a short time by using the agitating force, so that the temperature of the cooling water can be prevented from partially abruptly rising, so that a temperature delay effect can be obtained, and at the same time, the cooling water temperature is uniform. to increase the rapid cooling and constant temperature effect.

Here, in a preferred embodiment according to the present invention, when there are two stirring blades 410, as shown in [Fig. 3] and [Fig. 6], the cooling water supplied through the cooling water pipe 500 has two stirring blades. By configuring to be supplied between the 410, the stirring blades 410 installed above disperse the cooling water toward the constant temperature furnace main body 100 to increase the dispersion effect, and at the same time, the stirring blades 410 below move the cooling water upward It is preferable to configure so that the dispersion effect can be further enhanced by dispersing.

In addition, in a preferred embodiment according to the present invention, when there are several stirring blades 410, the cooling water pipe 500 is configured to supply cooling water to any one of the neighboring stirring blades 410. By doing so, it is preferable to configure the stirring effect to be further enhanced through a plurality of stirring blades 410. At this time, the stirring blades 410 under the cooling pipe 500 may all be manufactured to rotate in the same direction, but rotate in different directions or are installed to rotate alternately one by one, so that the stirring effect of the cooling water can be further enhanced. it is desirable

On the other hand, as shown in [Figs. 3] and [Fig. 6], a flow meter 510 and a valve 520 are mounted on the cooling water pipe 500, such that the internal capacity of the constant temperature furnace main body 100 and the volume of the object to be heat treated, etc. Anyone skilled in the art should be able to easily understand that an appropriate amount of cooling water should be supplied in consideration of the above. In this case, the valve 520 may be composed of various valves such as a safety valve, a check valve, and a solenoid valve to stably supply cooling water and to shut off the supply of cooling water when a dangerous situation occurs so as to be used safely.

As described above, the present invention arranges the cooling water discharged from the cooling water pipe installed in the main body of the constant temperature furnace so that it is made under the uppermost stirring blade, so that the stirring effect is well achieved through the stirring blade, so that the temperature of the cooling water partially rises rapidly This prevents it from happening so that it can be used stably and safely.

100: constant temperature furnace body
100', 100": inside, outside
110: entrance
111: door
200: actuator
300: heater
400: stirring means
410: stirring wing
420: actuator
500: cooling water

Claims (4)

a constant temperature furnace main body 100 having an inlet 110 formed at an upper portion, an openable and closeable door 111 provided at the inlet 110, and made of a refractory material; an actuator 200 installed outside the constant temperature furnace main body 100 to open and close the door 111; at least one heater 300 installed on the constant temperature furnace main body 100 and having one side exposed in the constant temperature furnace main body 100 to adjust the internal temperature; and at least one agitation vane 410 installed on a shaft rotating in place with one side exposed inside the constant temperature furnace body 100 and the other side exposed outside the constant temperature furnace body 100, and the outside of the constant temperature furnace body 100. In a constant temperature furnace for heat treatment comprising a stirring means 400 including an actuator 420 installed on the stirring blades 410 to forcibly rotate,
A cooling water pipe 500 for supplying cooling water from the outside is installed in the constant temperature furnace main body 100, and the cooling water pipe 500 supplies cooling water under the stirring blades 410 so as to generate rotational force of the stirring blades 410. A constant temperature furnace for heat treatment, characterized in that the cooling water is supplied so that the cooling water is evenly spread in the constant temperature furnace main body 100.
In paragraph 1,
The constant temperature furnace body 100,
The inner surface (100') is finished with SUS 304 with a thickness of 3 mm to 20 mm,
A constant temperature furnace for heat treatment, characterized in that the outer surface (100 ") is finished with a general iron plate having a thickness of 4.5 mm to 20 mm.
In paragraph 1,
One side of the door 111 is mounted to the constant temperature furnace body 100 so as to be rotatable in place using a hinge,
The actuator 200 is a constant temperature furnace for heat treatment, characterized in that one side is installed to rotate in place outside the constant temperature furnace main body 100 and the other side is installed rotatably on the door 111.
In any one of claims 1 to 3,
The cooling water pipe 500,
When the stirring blades 410 are two, it is configured to supply cooling water between the two stirring blades 410,
When there are several stirring blades 410, the cooling water is supplied to one of the neighboring stirring blades 410.

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