KR102246329B1 - Holding furnace system with low energy cost and stirring function - Google Patents

Abstract

The present invention relates to a melting furnace for melting metal ingots or scraps, and more specifically, to a low-energy depositing, melting, and holding furnace system with a stirring function, which circulates and rotates molten metal in a melting chamber to increase the melting rate of ingots, makes the density and temperature of the molten metal uniform, and floats impurities to improve the quality of the molten metal. According to the present invention, the low-energy depositing, melting, and holding furnace system with a stirring function comprises: a melting chamber; a melting heater installed in the melting chamber to melt fed ingots; a heat insulation chamber connected to the melting chamber to introduce molten metal; a heat insulation heater installed in the heat insulation chamber to heat the molten metal so that the same maintains a predetermined temperature; a tapping chamber connected to the heat insulation chamber to introduce the molten metal and drain the same to the outside; and agitating blades installed in the melting chamber to circulate and stir the molten metal.

Description

Holding furnace system with low energy cost and stirring function

The present invention relates to a holding furnace for dissolving metal ingots or scraps, and more particularly, by rotating the molten metal in a melting chamber to increase the dissolution rate of the ingot, the density and temperature of the molten metal are uniform as a whole, and impurities are floated. Thus, it relates to a low-energy immersion melting holding furnace system having an excellent stirring function of the quality of the molten metal.

The melting furnace melts metal ingots and scraps with high heat, and then pours the molten metal into a mold to produce related products through die casting or casting.

In the case of aluminum, ingots and scraps melt at about 700°C to 740°C, and aluminum alloys are widely used as various structural materials and mechanical parts because they are superior to other metals in castability, processability, and specific strength.

As a prior art for a melting furnace, registered patent 10-1669135 "combined melting furnace" and registered patent 10-0598920 "nonferrous metal rapid melting furnace" have been disclosed.

The melting furnace is provided with a melting chamber for dissolving the ingot, a warming chamber for maintaining the dissolved molten metal at a constant temperature, and a tapping chamber for outflowing the molten metal to the outside.

In the melting chamber, the injected ingot is heated by heating with a heat source such as a burner flame, high voltage arc, and high heat heater.In the prior art, the molten metal in the melting chamber is stagnant, so the temperature and density of the molten metal differ depending on the distance from the heat source. And, there is a problem that the dissolution rate is slowed when the injected ingot moves away from the heat source.

The present invention is an invention conceived to solve the problem of the holding furnace according to the prior art. By circulating and rotating the molten metal in the melting chamber so that the molten metal is stirred, the molten metal in the melting chamber has a uniform temperature and density as a whole. It is an object of the present invention to provide a low-energy immersion dissolution holding furnace system with an agitation function that increases dissolution rate.

In addition, it is another object of the present invention to provide a low-energy immersion melting holding furnace system having an agitation function in which the quality of the molten metal is improved by supplying nitrogen to the molten metal in the melting chamber to float water in the molten metal.

The low-energy immersion melting holding furnace system having a stirring function according to the present invention for achieving this object is

Melting chamber;

A dissolution heater installed in the dissolution chamber to dissolve the inputted ingot;

A warming chamber connected to the melting chamber into which molten metal flows;

A thermal insulation heater installed in the thermal insulation chamber to heat the molten metal to maintain a constant temperature;

A tapping chamber connected to the warming chamber to allow molten metal to flow therein and outflow;

It is installed in the melting chamber to circulate and stir the molten metal so that the stirring blade; comprises a.

And a branch guide block installed adjacent to the stirring blade in the melting chamber to allow the circulating molten metal to branch and pass through, and characterized in that it further comprises,

A flow path is provided on the rotating shaft of the stirring blade,

It characterized in that it further comprises a; nitrogen supply pump for supplying nitrogen to the molten metal of the melting chamber through the flow path,

A nozzle is provided at an end of the tube supplying nitrogen of the nitrogen supply pump, the nozzle is coupled to a mounting plate, and a coupling plate is provided on a rotating shaft of the stirring blade,

The mounting plate and the coupling plate are coupled in a one-touch manner with a one-touch coupling block,

The one-touch coupling block

A first block provided on the mounting plate and provided with a pair of fixing arms provided to protrude to both sides,

A second block provided on the coupling plate and having a fitting groove into which the first block is inserted, and a second block provided in the fitting groove and formed with an insertion groove into which the fixing arm is inserted,

A pull-in preventing weight provided in the first block to prevent retraction of the fixed arm and a handler that induces the lift-off of the pull-in preventing weight and is hingeably coupled to the first block, and a wire connecting the handler and the pull-in preventing weight Consists of including an intrusion prevention means comprising a,

When the first block is inserted into the fitting groove and the handler is operated, the push-in prevention addition moves between the pair of fixed arms and the pair of fixed arms is inserted into the pull-in groove to insert the first block into the second block. Fixed on,

It is characterized in that the retraction of the pair of fixing arms is not allowed by a retraction prevention addition positioned between the pair of fixing arms.

The low-energy immersion melting holding furnace system with agitation function according to the present invention is agitated while the molten metal in the melting chamber is circulated, so that the quality of the molten metal is excellent, the dissolution rate of the ingot is high, and the molten metal is As a product with high purity, it is a very useful invention for industrial development.

1 is a plan view of a low-energy immersion melting holding furnace system having a stirring function according to the present invention.
Figure 2 is a structural diagram of the AA section in Figure 1;
3 is a structural diagram of a BB section in FIG. 2;
4 is a structural diagram of a CC section in FIG. 1;
5 is a structural diagram of a DD section in FIG. 1;
6 is a view in which the coupling part of the rotation shaft of the stirring blade and the tube of the Jinso supply pump as a main part.
7 is a view showing the configuration and operation mechanism of the one-touch coupling block according to the present invention.

Hereinafter, a low-energy immersion melting holding furnace system having a stirring function according to the present invention will be described in more detail with reference to the drawings.

Before describing in more detail about the low-energy immersion melting holding furnace system having a stirring function according to the present invention,

The present invention will be described in detail in the text of the bar, implementation (態樣, aspect) (or embodiment) that can apply various changes and have various forms. However, this is not intended to limit the present invention to a specific form of disclosure, and it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

In each drawing, the same reference numerals, in particular the number of tens and ones, or the same reference numerals with the same tens, ones, and alphabet indicate members having the same or similar functions, and unless otherwise specified, each of the drawings. The member indicated by the reference numeral can be identified as a member conforming to these criteria.

In addition, components in each drawing are expressed by exaggeratingly large (or thick) or small (or thin) or simplified their size or thickness in consideration of the convenience of understanding, but the scope of protection of the present invention is limited by this. It shouldn't be.

The terms used in this specification are only used to describe specific embodiments (sun, 態樣, aspect) (or embodiments), and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as ~comprise~ or ~consist~ are intended to designate the existence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other features It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of the presence or addition.

Unless otherwise defined, all terms used herein including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Does not.

As shown in the drawing, the low-energy immersion melting holding furnace system having a stirring function according to the present invention includes a wall 10 that makes a melting chamber 20, a warming chamber 30, and a tapping chamber 40, and a melting heater 50. , A heat insulation heater 60, a stirring blade 70, a branch guide block 80, a nitrogen supply pump 90, and the like.

The wall 10 that makes the melting chamber 20, the warming chamber 30, and the tapping chamber 40 is made of refractory material to increase heat storage and minimize dissipation loss, and these refractories are generally insulating boards, thermal insulation It is composed of bricks, refractory bricks, and castables.

The dissolution chamber 20 is provided with an inlet 21 into which the aluminum ingot is introduced, a dissolution heater 50 for dissolving the injected ingot, and a stirring blade 70 for circulating and rotating the molten metal.

An outlet 23 is formed in the partition wall 22 between the melting chamber 20 and the warming chamber 30, so that the molten metal dissolved in the melting chamber 20 flows out to the warming chamber 30. At this time, the outlet 23 is formed on the upper side of the partition wall 22 and is located on the lower layer of the melting chamber 20 so that the undissolved ingot does not flow out to the warming chamber 30.

The melting heater 50 is provided with a plurality, and is disposed adjacent to the partition wall 22 on which the outlet 23 is formed, so that the molten metal completely dissolved while passing through the melting heater 50 immediately before is transferred to the warming chamber 30. It may be desirable to allow it to spill.

The stirring blade 70 allows the molten metal to be stirred while circulating and rotating in the melting chamber 20, so that the molten metal in the melting chamber 20 has an overall uniform temperature and density to increase the quality of the molten metal, and the dissolution rate of the injected ingot Raise

A plurality of the stirring blades 70 are provided in the vertical direction and rise and fall according to the level of the molten metal, so that the molten metal of the upper and lower layers rotates circulating at a uniform speed.

The stirring blade 70 maintains the temperature of the molten metal at a set temperature by adjusting the rotational speed according to the temperature of the molten metal. When the molten metal is overheated, the rotational speed of the stirring blade 70 is reduced to gradually purify the molten metal, and when the temperature of the molten metal decreases due to the introduction of a new ingot, the rotation speed of the stirring blade 70 is increased to rapidly circulate the molten metal. Make it possible.

The rotating shaft 71 provided with the stirring blade 70 is rotated by the motor 73, and the frame 74 on which the motor 73 and the rotating shaft 71 are mounted rises and falls along the guide rod 75. .

A flow path 72 is formed on the rotation shaft 71 of the stirring blade 70, and the upper flow path 72 of the rotation shaft 71 is connected to the nitrogen supply pump 90 by a tube 91, so that the melting chamber 20 ), nitrogen is supplied to the molten metal. The nitrogen supplied to the molten metal floats impurities contained in the molten metal, and the molten metal promotes degassing, thereby increasing the purity of the molten metal.

A branch guide block 80 is installed in the melting chamber 20 so that the molten metal located at the center and the outer side of the melting chamber 20 actively circulates and rotates and passes through the melting heater 50.

3 and 5, the stirring blade 70 is arranged to be skewed toward the opposite side of the inlet 21 in the melting chamber 20, and the branch guide block 80 is the outlet 23 in the melting chamber 20. ) And the dissolution heater 50 are disposed at the corners of the disposed side, and a space 81 is formed between the branch guide block 80 and the inner wall of the dissolution chamber 20 so that the stirring blade 70 is rotated. As a result, the molten metal is branched to the inside and outside of the branch guide block 80, and the molten metal branched to the outside passes through the separation space 81 and moves along the inner wall of the melting chamber 20, passing through the melting heater 50, and the melting chamber 20 ), and the molten metal branched to the outside rotates inward in the melting chamber 20 through the melting heater 50 while moving from the branch guide block 80 to the inside rounded, and the branch guide block ( The molten metal that is branched and moved inward and outward at 80) meets at the inlet port 21 and is mixed and circulated.

In the warming chamber 30, the molten metal dissolved in the melting chamber 20 is introduced and stored through the outlet 23, and the tapping chamber 40 is connected to the warming chamber 30 from the lower side to provide an internal space. And a partition wall 32 is formed on the upper side to be partitioned.

An insulating heater 60 is installed in the warming chamber 30 to maintain the stored molten metal at a constant temperature.

Referring to FIG. 6, a nozzle 93 is provided at an end of the tube 91 of the nitrogen supply pump, and the nozzle is coupled to the mounting plate 95. And the mounting plate 95 is coupled to the coupling plate 77 provided on the rotating shaft 71 of the stirring blade (70). The nozzle 93 is seated in the seating groove 78 of the rotating shaft 71 to supply nitrogen to the flow path 72 of the rotating shaft 71.

The mounting plate 95 and the coupling plate 77 are simply and quickly operated with one-touch operation without the need for a separate tool through a one-touch coupling block TB composed of a first block B1 and a second block B2. Combined and separated.

The one-touch coupling block (TB) is provided on the mounting plate (95), as shown in Figure 7, a first block (B1) provided with a pair of fixing arms (B13) provided so as to protrude to both sides, and A second block provided on the plate 77 and having a fitting groove (B21) into which the first block (B1) is inserted, and an entry groove (B23) provided in the fitting groove (B21) and into which the fixing arm (B13) is inserted (B2) and, provided in the first block (B1) to induce the lifting and lowering of the pull-in preventing weight (B33) and the pull-in preventing weight (B33), which are provided in the fixing arm (B13) to prevent the retraction of the fixed arm (B13), and the first block ( Consisting of including a pull-in preventing means (B3) including a handler (B31) hingeably coupled to B1) and a wire (B35) connecting the handler (B31) and the pull-in preventing weight (B33),

When the first block (B1) is inserted into the fitting groove (B21) and the handler (B31) is operated, the pull-in prevention weight (B33) moves between the pair of fixing arms (B13) and the pair of The first block (B1) is fixed to the second block (B2) by inserting the fixing arm (B13) into the retracting groove (B23), and a retracting prevention weight (B33) is positioned between the pair of fixing arms (B13). Thus, it is characterized in that the retraction of the pair of fixing arms (B13) is not allowed.

Hereinafter, referring to FIG. 7, each configuration will be described in more detail,

First, the first block (B1) and the second block (B2) are not shown in a detailed perspective view in the drawing, but are made of a cylinder or a polygonal column,

First of all, the second block (B2) is provided in the coupling plate (77), the first block (B1) is inserted into the fitting groove (B21) is formed in the center, both sides of the fitting groove (B21) A groove B23 is formed, and the lead-in groove B23 is provided at a position corresponding to the position of the fixing arm B13 when the first block B1 is fitted into the fitting groove B21.

Again, the first block (B1) is a block of a cylinder or a polygonal column as mentioned above, the lower portion is made to be inserted into the fitting groove (B21), as shown in the figure, in the center of the T-shaped T-shaped space ( B11) is formed, the T-shaped space portion (B11) and communicated with the draw path (B12) open to both sides of the second block (B2) is formed, the center of the draw path (B12) to be described later The receiving portion (B335) is provided with a pull-in prevention weight (B33) is formed.

First, the fixing arm (B13) will be described, the first block (B1) is provided with a fixing arm (B13) is provided so as to protrude to both sides, the fixing arm (B13) is provided in the withdrawal path (B12), By the operation of the pull-in preventing weight (B33), the first block (B1) is made to protrude to both sides so that it can be fitted into the pull-in groove (B23).

Each outer side of the fixed arm (B13) is further provided with a support wing (B131), and a return elastic body (B133) surrounding the fixed arm (B13) is between the support wing (B131) and the edge of the first block (B1). Is provided, and the fixing arm (B13) is configured to receive an elastic force to be restored in the inner direction of the first block (B1), and the fixing arm (B13) protrudes when the first block (B1) is inserted into or removed from the second block (B2). It is made so that the operation can be performed smoothly.

In addition, a corresponding inclined portion B135 is further provided at the inner end of the fixed arm B13, which is for naturally pushing the fixed arm B13 to both sides when the inlet preventing weight B33, which will be described later, moves.

A pressing plate B17 for pressing and pressing the surface of the mounting plate 95 is provided on the outer periphery of the first block B1, and the pressing plate B17 is elastically supported by a spring B18.

The handlers B31 are further provided on both sides of the first block B1, and more precisely, on both sides of the upper side of the first block B1 according to Fig. 7A, and the handler B31 is provided with a pull-in preventing means B3. ) As a configuration, hereinafter, to be described in more detail with respect to the intrusion prevention means (B3).

The pull-in preventing means (B3) is provided in the first block (B1) to protrude the pair of fixing arms (B13) to both sides, and then the pull-in preventing weight (B33) to prevent the retraction of the pair, and the first It comprises a handler (B31) hinged to the block (B1), and a wire (B35) connecting the handler (B31) and the pull-in prevention weight (B33).

First, as mentioned above, the pull-in prevention weight (B33) is seated in the receiving portion (B335), and is located at the bottom between the pair of fixing arms (B13) based on Figure 7a, the pull-in prevention weight (B33) An entry slope (B331) that is in close contact with the corresponding slope (B135) is provided at the end of, and a compression spring (B333) supporting the entry prevention weight (B33) is further provided in the receiving portion (B335). have.

The compression spring (B333) is a spring having an elastic force in the direction of restoring the inlet prevention weight (B33), where the restoring direction refers to a position in a state when the fixing arm (B13) does not protrude, as shown in FIG. 7A. .

Therefore, when the intrusion prevention weight (B33) moves between the pair of fixing arms (B13), as shown in Fig. 7B, the fixing arms (B13) naturally open by the entry guide and the corresponding inclined part (B135) to the first block ( B1) It protrudes to both sides, and unless the position of the pull-in prevention weight is changed, the fixing arms (B13) cannot retreat to the inside again, thereby reducing the fixing force of the first block (B1) and the second block (B2). I can keep it.

Again, the handler (B31) is a member hinged to both upper sides of the first block (B1) through the first hinge (B311) based on the direction of FIG. 7A, and the handler (B31) is shown in [ As shown in B], one surface may be moved so as to be in close contact with the lateral direction of the first block B1.

The handler (B31) is a member that controls the movement of the pull-in preventing weight (B33), the handler (B31) and the pull-in preventing weight (B33) are connected by a wire (B35) as shown in the drawing, the wire (B35) ) In order to prevent damage, a first roller (B15) is provided at the inner edge of the T-shaped space (B11) to support the wire (B35), and the end of the T-shaped space (B11), that is, The second roller B16 is also provided in a portion where the wire B35 is exposed.

With the above configuration, as shown in Fig. 7B, after inserting the first block B1 into the second block B2, and folding the pair of handlers B31, the wire B35 is pulled. The pull-in preventing weight (B33) is moved, and due to the movement of the pull-in preventing weight (B33), the pair of fixing arms (B13) protrude to both sides of the first block (B1) and are inserted into the pull-in groove (B23). This prevents the first block B1 from being separated from the second block B2.

At this time, in order to maintain the folded state of the handler (B31), the first magnet (M1) on the surface of the first block (B1) and the handler (B31) in close contact with each other based on the folded state of the handler (B31). ) And a second magnet (M2), and prevents the handler (B31) from being unfolded arbitrarily by allowing them to be fixed by the manpower to prevent the retracting prevention weight (B33) from being returned.

In addition, in order to separate the first block (B1) from the second block (B2), the handler (B31) must be unfolded again, and the handler (B31) is secured by magnetism to the first block (B1). As it is attached, it is difficult for the user to open the handler B31, and the present invention further includes a holding handle B313 hinged to the second hinge part B312 to the handler B31 to compensate for this. I'm doing it.

Therefore, after the holding handle B313 is tilted as shown in FIG. 7B, the user can easily open the handler B31 by holding the holding handle B313, and when the handler B31 is unfolded, the pull-in prevention weight B33 ) By the elastic restoring force of the compression spring (B333) that supported the inlet prevention weight (B33) to the receiving portion (B335) as shown in Fig. 3 [A], the pair of fixed arms (B13) is a return elastic body The elastic force of (B133) leads to the inside of the first block (B1), and maintains a state capable of separating the first block (B1) from the second block (B2).

That is, in the present invention, the mounting plate 95 and the coupling plate 77 can be more easily fixed and separated by the one-touch coupling block TB as described above, so that the effect of greatly improving the usability can be expected.

In the above description of the present invention, a low-energy immersion melting holding furnace system having a stirring function having a specific shape and structure has been described with reference to the accompanying drawings, but the present invention can be variously modified and changed by those skilled in the art. And changes should be construed as belonging to the protection scope of the present invention.

10: wall 20: melting chamber
30: warming room 40: tapping room
50: melting heater 60: warming heater
70: stirring blade 80: branch guide block
90: nitrogen supply pump
TB: One-touch coupling block B1: First block
B11: T-shaped space part B12: Withdrawal route
B13: Fixed arm B131: Support wing
B133: return elastic body B135: corresponding slope
B15: first roller B16: second roller
B2: 2nd block
B21: Fitting groove B23: Entry groove
B3: Inflow prevention means
B31: handler B311: first hinge part
B312: second hinge part B313: holding handle
B33: Inlet prevention weight B331: Entrance slope
B333: compression spring B335: receiving part
B35: wire
M1: 1st magnet M2: 2nd magnet

Claims (4)

Melting chamber;
A dissolution heater installed in the dissolution chamber to dissolve the inputted ingot;
A warming chamber connected to the melting chamber into which molten metal flows;
A thermal insulation heater installed in the thermal insulation chamber to heat the molten metal to maintain a constant temperature;
A tapping chamber connected to the warming chamber to allow molten metal to flow therein and to flow out the molten metal to the outside;
A stirring blade installed in the melting chamber to circulate and stir the molten metal;
A low-energy immersion melting holding furnace system having a stirring function comprising a branching guide block that forms a spaced space between the inner wall of the melting chamber and is installed adjacent to the stirring blade so that the circulating molten metal diverges and passes through the inner and outer sides of the stirring blade. . delete The method of claim 1,
A flow path is provided on the rotating shaft of the stirring blade,
A nitrogen supply pump for supplying nitrogen to the molten metal of the melting chamber through the flow path; a low-energy immersion melting holding furnace system having a stirring function, characterized in that it further comprises. The method of claim 3,
A nozzle is provided at an end of the tube for supplying nitrogen of the nitrogen supply pump, the nozzle is coupled to a mounting plate, and a coupling plate is provided on a rotating shaft of the stirring blade,
The mounting plate and the coupling plate are coupled in a one-touch manner with a one-touch coupling block,

The one-touch coupling block
A first block provided on the mounting plate and provided with a pair of fixing arms provided to protrude to both sides,
A second block provided on the coupling plate and having a fitting groove into which the first block is inserted, and a second block provided in the fitting groove and formed with an insertion groove into which the fixing arm is inserted,
A pull-in preventing weight provided in the first block to prevent retraction of the fixed arm and a handler that induces the lift-off of the pull-in preventing weight and is hingeably coupled to the first block, and a wire connecting the handler and the pull-in preventing weight Consists of including an intrusion prevention means comprising a,
When the first block is inserted into the fitting groove and the handler is operated, the push-in prevention addition moves between the pair of fixed arms and the pair of fixed arms is inserted into the inlet groove to insert the first block into the second block. Fixed on,
A low-energy immersion melting holding furnace system having an agitation function, characterized in that the retraction of the pair of fixed arms is prevented by being positioned between the pair of fixed arms.

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