KR101819853B1 - forming apparatus of induction - Google Patents

Abstract

The present invention relates to an induction molding device, and more specifically, to an induction molding device, which comprises: a double tube-shaped housing composed of an inner space and an outer space by a cylindrical bracket inserted thereinto; a base cap fastened to a lower portion of the housing; and an upper cap fastened to the upper portion of the housing, wherein an air inlet for evacuating an external space is formed on the side surface of the housing. The induction molding device of the present invention can easily manufacture induction, reduces a defective rate at the time of manufacturing an induction to improve productivity thereby, has excellent temperature-rising and temperature-maintaining properties, and does not require an additional process due to defect of condensed water.

Description

A forming apparatus of induction

The present invention relates to an induction molding machine, and more particularly, to an induction molding machine including a double pipe-shaped container made of an internal space portion and an external space portion by a cylindrical bracket inserted therein, a base cap fastened to a lower portion of the container, And an air inlet for evacuating the outer space is formed on a side surface of the container.

An induction boiler is an indirect boiler that moves water while vibrating and rotating when it passes through a tube that induces a magnetic induction (induction), and when it flows continuously and narrowly and irregularly, it accelerates rotation and vibration, Type boiler.

A first embodiment of the prior art of the induction boiler is disclosed in Patent Publication No. 0762951, which has a water storage chamber in which water is allowed to flow in and out of the circumference, and both ends of the water storage chamber, A cylindrical outer shell which surrounds the first cylindrical body and has both ends opened to form the water storage chamber between the outer cylindrical body and the outer cylindrical body; Wherein the outer circumferential surface of the outer shell abuts on the first flanges protruded from the upper and lower ends of the first susceptor, and the metal is formed between the first flanges and the outer circumferential surface of the outer shell, Cylindrical body; And a first magnetic field inducing means provided on an inner circumferential surface of the cylindrical body to apply heat to the water storage chamber, wherein the water stored in the water storage chamber is a magnetic field induced by the first magnetic field guiding means And the heater is heated to a predetermined temperature by heat generated in response to the temperature of the induction boiler.

A second embodiment of the prior art is an induction boiler using a magnetic field in Japanese Laid-Open Patent Publication No. 2015-0135929, comprising: a main body; Wherein the main body includes a heater unit protective cover having a pipe inserting passage formed therein for inserting a heating body pipe therein; an inner tube wrapped around an outer surface of the insulating coil on the inner surface of the heater unit protective cover; Upper and lower spacers formed on upper and lower portions of the inner tube to form a gap therebetween; And a terminal for supplying power to the insulation coil is formed on the upper portion of the interval maintaining portion. An upper cover formed on an upper portion of the control unit; And a heating body pipe fixing part is formed on the upper part or the upper / lower part so as to fix the heating body pipe.

In the third embodiment of the prior art, the inner pipe 100 is passed through the No. 1418924, and the outer surface of the inner pipe is formed so as to surround the induction coil wound with the layered layer and the induction coil, A heater part formed of an outer pipe filled with the outer pipe; An upper porous finishing plate and a lower porous finishing plate, the upper porous finishing plate and the lower porous finishing plate being inserted into the upper porous finishing plate and the lower finishing finger plate, respectively, so as to fix and align the heater units in a row or in multiple rows; A heater installed in a through hole formed in a publicly known fingerboard to form a lower collector pipe having a fluid inlet to which fluid is introduced and an upper collector pipe having a fluid outlet through which heated fluid is discharged, Supply plate; A lower first collecting part formed at a front of the first heater part and a lower part collecting part formed at a lower part of the lower part of the upper collecting part, An upper first partition having a first electromagnetic opening and closing part formed behind the first heater part of the water tube; A lower second partition having a second electromagnetic opening and closing part formed in front of the second heater part in the lower collector pipe and an upper second partition formed in the rear of the second heater part in the upper collector pipe; A lower third partition formed in the lower collecting pipe in the front of the third heater and a third partition formed in the upper collecting pipe in the rear of the third heater to form a fourth electromagnetic opening / And an induction functional boiler using electrical energy is disclosed in which a wheel is formed so as to be movable in the main body.

However, the induction used in the conventional induction boiler is limited to use as a coil as a magnetic field inducing means, and it is also difficult to maintain the temperature and the temperature, and a further process is required due to the defective condensed water.

Disclosure of the Invention The present invention has been conceived to solve the problems described above, and it is an object of the present invention to provide an induction molding machine in which an induction with an air spring (air suspension) is formed in place of a coil by magnetic field inducing means to prevent condensation water failure, I want to.

The induction molding machine according to the present invention comprises a double pipe-shaped housing made of a cylindrical bracket inserted into an inner space part and an outer space part, a base cap fastened to the lower part of the housing and an upper cap fastened to the upper part of the housing And an air inlet for evacuating the external space is formed on the side surface of the housing.

INDUSTRIAL APPLICABILITY The induction molding machine of the present invention has a remarkable effect that it is easy to manufacture the induction, the defective rate at the time of manufacturing is low, the productivity due to the improvement can be improved, the temperature and temperature are maintained well, .

1 is a photograph of an induction molding machine of the present invention.
2 is a sectional schematic view of the induction molding machine of the present invention.
3 is an outline view of an induction inserted into the induction molding machine of the present invention.
4 is a perspective view showing a coil tube of an induction inserted into the induction molding machine of the present invention.
5 is a detailed view of a part of the induction coil tube of the present invention.
6 is a perspective view of another embodiment of the induction coil tube of the present invention.
7 is a view showing the state of use of the induction molding machine of the present invention.
8 is a view showing an operation state of the induction molding machine jig device of the present invention.
9 is a photograph of the induction molding machine jig device of the present invention.
10 is a partial photograph of the jig device of the induction molding machine of the present invention.

The induction molding machine according to the present invention comprises a double pipe-shaped housing 110 made up of an internal space part 112 and an external space part 113 formed by a cylindrical bracket 140 inserted in the interior of the housing 110, And an upper cap 120 fastened to the upper portion of the housing 110. An air inlet 111 for evacuating the outer space 113 is formed on the side surface of the housing 110 .

The upper and lower ends of the rubber 230 are connected to the upper and lower ends of the upper cap 120 and the base cap 120. The upper and lower ends of the rubber 230 are inserted into the inner space 112 of the cylindrical bracket 140, A plurality of holes 151 are formed in a circumferential surface of the cylindrical bracket 140 so that the outer space portion 113 of the cylindrical bracket 140 is vacuumed, Is made to adhere to the inner surface of the cylindrical bracket 140.

A cylindrical container 210 having a coil pipe 220 mounted therein is inserted into the hollow hole of the hollow rubber 230 inserted into the cylindrical bracket 140.

The induction 200 formed by the induction molding machine 100 includes a cylindrical container 210 having an opening formed at a lower portion thereof and a hollow tube shaped coil 210 inserted into the cylindrical container 210, A synthetic resin 240 filled in the cylindrical container 210 so that the coil pipe 220 is fixed to the inside of the cylindrical container 210 and a hollow rubber 230 surrounding the outer circumference of the cylindrical container 210. [ ). ≪ / RTI >

Hereinafter, the induction molding machine of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a photograph of the induction molding machine of the present invention, and FIG. 2 is a sectional schematic view of the induction molding machine of the present invention.

1 and 2, the induction molding machine 100 according to the present invention includes a housing 110 having a double pipe structure including an inner space 112 and an outer space 113, A base cap 130 to be fastened and an upper cap 120 fastened to the upper portion of the housing 110.

Particularly, when the cylindrical bracket 140 is inserted into the housing 110, the inside of the housing 110 is divided into the inner space 112 and the outer space 113 by the cylindrical bracket 140 do.

That is, the outer diameter of the cylindrical bracket 140 is smaller than the inner diameter of the housing 110, so that the housing 110 can be separated from the inner space 112 and the outer space 113 by the cylindrical bracket 140 The cylindrical bracket 140 is preferably positioned on the inner circumference of the housing 110 on the concentric circle of the housing 110.

A plurality of holes 141 are formed in the outer circumferential surface of the cylindrical bracket 140.

The base cap 130 is formed with an entrance 131 for introducing or discharging cooling water into the interior of the container 210 inserted into the internal space 112 of the housing 110, And an air inlet 111 for evacuating the external space 113 is formed on the side surface.

The inlet port 131 may be formed separately from the through hole means for flowing the cooling water into the inner space portion 112 of the housing 110 and the through hole means for discharging the cooling water.

The upper and lower ends of the rubber 230 are inserted into the upper and lower ends of the upper and lower caps 120 and 130, respectively, ).

The induction 200 is formed by inserting the cylindrical container 210 into the hollow hole of the rubber 230 and fastening it with the hollow rubber 230 which is already inserted into the cylindrical bracket 140.

The rubber 230 can be made of both natural rubber and synthetic rubber. Particularly, vulcanized rubber or EPDM is used.

The relationship in which the cooling water moves to the inside of the container 210 mounted inside the cylindrical bracket 140 and the relationship in which the induction 200 is formed will be described in detail below.

The method of fastening the housing 110, the upper cap 120, the base cap 130, and the cylindrical bracket 140 is well known in the art, and a detailed description thereof has been omitted.

FIG. 3 is an outline view of an induction inserted into the induction molding machine of the present invention, FIG. 4 is a perspective view showing a coil tube of an induction inserted into the induction molding machine of the present invention, and FIG. 5 is a detail view of a part of the induction coil tube of the present invention .

As shown in FIG. 3, the induction 200 molded by the induction molding machine 100 of the present invention includes a cylindrical container 210 having an opening at a lower portion thereof, A synthetic resin 240 filled in the cylindrical tube 210 to fix the coil tube 220 to the inside of the cylindrical tube 210 and a cylindrical tube 210 that surrounds the outer circumference of the cylindrical tube 210 And a rubber (230).

That is, after the coin tube 220 is inserted through the lower side opening of the cylindrical container 210, the inside of the cylindrical container 210 is filled with synthetic resin so that the coin tube 220 is inserted into the cylindrical container 210 .

The synthetic resin is made of an epoxy resin.

Epoxy resins are resistant to water and weather changes, have fast curing properties, and have a strong adhesive strength.

The rubber 230 mounted on the outer periphery of the cylindrical container 210 is hollow and inserted into the molding machine 100 as described above and then adhered to the outer periphery of the cylindrical container 210.

In particular, as shown in FIG. 4, the coin tube 220 is a coil spring-shaped hollow tube that allows fluid to flow therethrough, and is made of a metal material to allow electricity to flow through the surface of the hollow tube.

The coin tube 220 uses copper in consideration of corrosiveness and electrical conductivity.

When a vertical cross-sectional shape of the coin pipe 220 is formed in a rectangular shape and electric power is applied to the surface of the coin pipe 220, a gap between the horizontal surfaces of the coin pipes 220 stacked in the vertical direction, Since the vertical surfaces of all the coils 220 are all located on the same vertical line, the electric force applied to the inner central direction of the coils 220 and to the outside becomes uniform, The temperature difference was within 6 ° C.

On the other hand, the coils 220 are arranged such that the coil spacing becomes wider from the upper and lower ends toward the middle portion.

The coil spacing at both ends is preferably about 0.2 to 8 cm.

This is because the upper and lower ends of the coin tube 220 have many fastenings between different structures, so that more magnetic field can be generated as compared with the middle portion, so that faster and higher induction heating can be achieved.

The spacing of the coils 220 differs from the size (length, diameter) of the induction, but the widening of the coil gap from the upper and lower ends to the middle portion does not change.

6 is a perspective view of another embodiment of the induction coil tube of the present invention.

As shown in FIG. 6, the coil tube of the present invention may have a circular cross section.

7 is a state view showing the use of the induction molding machine of the present invention.

First, a rubber 230 in the form of a hollow body is inserted into a cylindrical bracket 140 mounted in the housing 110 of the induction molding machine 100 to fix the upper and lower ends, respectively, and then the cylindrical bracket 140 So that the hollow rubber 230 adheres to the inner surface of the cylindrical bracket 140.

In order to smoothly insert the cylindrical container 210 into which the coil tube 220 is inserted, the air is sucked through the air inlet 111 formed at one side of the housing 110 to the outside space of the cylindrical bracket 140 A plurality of holes 141 are formed in the outer periphery of the cylindrical bracket 140 so as to pass through the inner and outer portions of the cylindrical bracket 140. Therefore, 230 are attached to the inner periphery of the cylindrical bracket 140.

After the cylindrical container 210 is inserted into the hole 230 of the hollow cylindrical body 230, the vacuum state is released from the outer space of the cylindrical bracket 140, The rubber 230 is adhered to the outer periphery of the cylindrical container 210.

At this time, the inner pressure of the cylindrical bracket 140 is gradually increased from a low pressure to a high pressure so that the rubber 230 in the shape of a hollow body can be uniformly attached to the outer circumference of the cylindrical container 210.

Low pressure is 10kg / cm ² sorry, high pressure is such that as between the 10~30kg / cm ^2, the low pressure and high pressure are applied to different time depending on the nature of the rubber to each other, integrated 1 hour pressure.

If the pressure exceeds 30 kg / cm ² , the rubber 230 may be deformed or broken.

The cold hearth W is supplied to the hollow hole of the coin tube 220, and current is conducted to the metal surface.

That is, the surface temperature of the cylindrical container 210 is heated to maintain the surface temperature at 150 to 200 deg. C, while the surface temperature is within 6 deg. C by energizing the coin tube 220, Using distilled water to prevent scaling from occurring in the interior of the coin tube (220).

The coin tube 220 is made of a copper tube having a diameter of 0.2 to 0.4 mm, and a current of 0 to 50 A is allowed to flow for about one hour.

This is for the purpose of improving the characteristics of the rubber 230 surrounding the outer circumference of the cylindrical container 210 so that the surface of the molded rubber is constantly vulcanized so that the tensile strength or the like becomes constant.

FIG. 8 is a view showing the operation state of the induction molding machine jig apparatus of the present invention, FIG. 9 is a photograph of the induction molding machine jig apparatus of the present invention, and FIG. 10 is a photograph of a part of the induction molding machine jig apparatus of the present invention.

8 to 10, the present invention relates to an induction molding machine jig apparatus 300. The induction molding machine jig apparatus 300 includes an upper frame 310 and a lower frame 320, and an upper frame 310, a lower frame 320, And a vertical frame 330 supporting the upper frame 310 and the lower frame 320.

The upper frame 310 and the lower frame 320 are formed in the shape of a plate having a length in the left and right direction and an upper frame 310 is formed between the upper frame 310 and the lower frame 320, And the vertical frame 330 is coupled to the upper portion of the vertical frame 330.

A plurality of seating grooves 321 are formed on the upper surface of the lower frame 320 so as to be spaced along the longitudinal direction of the lower frame 320 so that the induction molding machine 200 having the upper opening is seated, A rotary plate 340 is installed at one end of the lower frame 320.

A plurality of seat belts 341 are protruded from the upper surface of the rotary plate 340 at predetermined intervals along the circumferential direction.

A cylindrical container 210, which is inserted into the induction molding machine 200, is seated on the seating table 341.

The upper frame 310 is provided with a conveying means 350 for linearly moving along the longitudinal direction of the upper frame 310. The conveying means 350 grips the cylindrical container 210 and forms an induction molding machine 200 And a gripper 360 for inserting the gripper 360 through an upper portion of the gripper 360.

Therefore, any one of the plurality of cylindrical containers 210 seated on the upper surface of the rotary plate 340 is gripped as the gripper 360. The gripper 360 is moved on the upper surface by the conveying means 350, The container 210 is stopped at the upper portion of the molding machine 200 to be inserted and the gripper 360 is lowered to insert the cylindrical container 210 into the upper portion of the molding machine 200.

After the cylindrical container 210 is inserted, the gripper 360 is moved up by the conveying means 350 in order to grip another cylindrical container 210 which is seated on the rotary plate 340.

Means for conveying the conveying means 350 and means for rotating the rotary plate 340 to place the cylindrical container 210 under the gripper 360 are well known and are not described in detail.

INDUSTRIAL APPLICABILITY The induction molding machine of the present invention has a remarkable effect that it is easy to manufacture the induction, the defective rate at the time of manufacturing is low, the productivity due to the improvement can be improved, the temperature and temperature are maintained well, .

100. Molding machine
110. Housing 111. Air inlet
112. Internal space part 113. External space part
120. Upper cap
130. Base cap 131. Doorway
140. Cylindrical bracket 141. Hole
200. Induction
210. Cylindrical vessel 220. Coil tube 230. Rubber
240. Synthetic resin
300. The jig device
310. Upper frame
320. Lower frame 321. Seat groove
330. Vertical frame
340. Rotating plate 341. Seat
350. Transfer means
360. Gripper
S. Safety valve T. Temperature sensor W. Coolant

Claims (3)

Shaped housing 110 made up of an internal space part 112 and an external space part 113 by a cylindrical bracket 140 inserted in the housing 110 and a base cap 130 And an upper cap 120 fastened to the upper portion of the housing 110. An air inlet 111 for evacuating the external space 113 is formed on the side surface of the housing 110, As a result,
The upper and lower ends of the rubber 230 are connected to the upper and lower ends of the upper cap 120 and the base cap 120. The upper and lower ends of the rubber 230 are inserted into the inner space 112 of the cylindrical bracket 140, A plurality of holes 151 are formed in a circumferential surface of the cylindrical bracket 140 so that the outer space portion 113 of the cylindrical bracket 140 is vacuumed, Is attached to the inner surface of the cylindrical bracket 140,
Wherein the cylindrical container (210) is inserted into the hollow hole of the hollow rubber body (230) inserted into the cylindrical bracket (140).

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