KR101563214B1 - Waste heat Recovery System With Air Cooled Condenser Of Injection Steam System - Google Patents

Abstract

The present invention relates to a waste heat recovery system with an air cooling-type condensing unit of an injection steam system. According to the present invention, the waste heat recovery system comprises a condensing unit which is provided on the top of a heating unit to liquefy steam, which is retrieved to reduce energy needed for supplying the steam, and then to transport the steam to the heating unit. Therefore, the water liquefied by the condensing unit can be transported to the heating unit due to gravity. Accordingly, the present invention is able to embody waste heat recovery by retrieving the steam used for processing an injection molding product and then reusing the same for generating steam, thereby enhancing driving efficiency of the heating unit which generates steam, and saving energy as well.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a waste heat recovery system having an air-cooled condensing unit of an injection steam system,

The present invention relates to a waste heat recovery system having an air-cooled condensing unit, and more particularly, to a waste heat recovery system having an air-cooled condensation unit that can be applied to an injection steam system.

The general process of injection molding is as follows.

First, when a synthetic resin raw material in the form of solid chips or pellets is fed into a hopper and supplied to the cylinder, the synthetic resin raw material is melted by the heat of friction between the band heater and the screw outside the cylinder.

The molten synthetic resin in a liquid state is injected into a mold having a predetermined shape and has a predetermined shape inside the mold. When the mold is cooled in this state, the synthetic resin in the mold So that the solid shape is maintained.

Thereafter, by separating the shape of the synthetic resin cooled from the mold, an injection-molded article having a predetermined solidified shape is obtained.

On the other hand, the injection-molded product is usually used as a video output device such as a TV or a monitor, or as a frame of a notebook computer. In order to provide an elegant appearance of electronic devices, a glass fiber component is added to the synthetic resin material to achieve a glossy effect.

When the molten molding is cooled and solidified due to the steam, the glass fiber contained in the molding is melted to some extent by the steam.

Generally, the steam is supplied at a pressure of 15 kg / cm 2 or more and heated to about 200 ° C., which is disadvantageous in that the maintenance cost for heating the steam is too large.

As a conventional technique for solving this problem, Korean Patent Laid-Open Publication No. 10-2012-0056097 (published on June 01, 2012) was available.

The above-mentioned prior art is an invention for cooling and heating an injection mold including a cooling system and a heating system. However, steam is used in a heating system, but recovery of steam is difficult and the heating time of the mold is limited.

In addition, in the case of the prior art, a configuration is adopted in which the recovery of steam is transferred to the cooling system to liquefy residual steam with cooling water, so that the waste heat recovery function for steam having a relatively high temperature is not provided, There is a problem in that the construction of the condensing unit is insufficient.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problem, and it is an object of the present invention to provide an injection molding machine capable of increasing the driving efficiency of a heating unit generating steam by reusing steam used for molding, And to provide a waste heat recovery system having an air-cooled condensing unit of the system.

A waste heat recovery system having an air-cooled condensing unit of an injection steam system according to the present invention includes: a heating unit for heating water from a water purification apparatus to generate steam; A steam supply pipe for supplying steam generated from the heating unit to an injection mold; A steam recovery pipe for recovering the steam from the injection mold; A condensing unit installed on the steam recovery pipe for liquefying the recovered steam; And a valve control unit for controlling the opening and closing of a plurality of valves installed on the steam supply pipe and the steam recovery pipe; Wherein the condensing unit includes: a condensing pipe connected to a part of the steam recovery pipe and having radiating fins for increasing a surface area; And a blowing fan for supplying air to the condensing pipe to liquefy the steam inside the condensing pipe; Wherein the condensing unit is provided on the upper side of the heating unit so that the water liquefied by the condensing unit can be moved to the heating unit by gravity, And the steam recovered through the steam recovery pipe from the injection mold is liquefied by water in the condensing unit and is then heated by the heating Unit.

The condensing unit lowers the temperature of the steam passing through the steam return pipe to 70 to 90 ° C to liquefy the steam.

The waste heat recovery system includes: a compressed air supply pipe for supplying compressed air to the injection mold; And a cooling water supply pipe for supplying cooling water to the injection mold; As shown in FIG.

A storage tank for storing liquefied water passing through the condensing pipe, the storage tank being located between the condensing pipe and the heating unit; And a movement intermittent valve controlled by the valve control unit and controlling the movement of water stored in the storage tank to the heating unit by gravity; As shown in FIG.

According to the present invention, it is possible to recover the waste heat by recovering the steam used for molding the molded product and reusing it for generating steam, thereby increasing the driving efficiency of the heating unit for generating steam.

1 is a block diagram showing the construction of a waste heat recovery system having an air-cooled condensing unit of an injection steam system according to the present invention.
Fig. 2 is a reference diagram for explaining the specific configuration and positional relationship of the condensing unit and the heating unit applied to the waste heat recovery system of Fig. 1;

Hereinafter, preferred embodiments according to the present invention will be described. For the sake of brevity of explanation, it is preferable to omit or compress known or duplicated descriptions as much as possible. For the sake of clarity, the drawings are concise.

1 is a block diagram showing the construction of a waste heat recovery system (hereinafter referred to as a waste heat recovery system) having an air-cooled condensation unit of an injection steam system according to the present invention.

1, a waste heat recovery system according to the present invention includes a heating unit 10, a steam supply pipe 20, a steam recovery pipe 30, a condensation unit 40, a valve control unit 50, (60) and a cooling water supply pipe (70).

The heating unit 10 is configured to receive purified water and sterilized water from the water purifier C and generate steam to generate steam. The heating unit 10 includes a heating tank 11, a heating tank 11, And a heater 12 disposed inside.

The steam supply pipe 20 is a pipe disposed between the heating unit 10 and the injection mold m to form a path through which steam generated from the heating unit 10 is supplied to the injection mold m.

The steam recovery pipe 30 is disposed between the injection mold m and the heating unit 10 and is formed separately from the steam supply pipe 20. The steam recovery pipe 30 is supplied to the injection mold m, Thereby forming a path through which the steam that has been subjected to the heating process is recovered.

That is, the waste heat recovery system according to the present invention forms a steam circulation line in which steam is supplied and recovered by the steam supply pipe 20 and the steam recovery pipe 30.

The condensing unit 40 is installed on the steam return pipe 30 and serves to liquefy the recovered steam through cooling. The condensing unit 40 includes a condensing pipe 42, a blowing fan 44, a storage tank 46, and a movable intermittent valve 48 as shown in FIG.

The condensing pipe 42 is installed on a part of the steam return pipe 30 so that the length of the condensing pipe 42 is extended so as to secure a sufficient time for the steam to be condensed. The condensing pipe (42) may be provided with radiating fins (P) for enhancing the condensing efficiency of the condensing unit (40). The radiating fins P are installed integrally or in a combined form in the condensing pipe 42 to increase the surface area of the condensing pipe 42 and serve to assist in rapidly liquefying the passing steam to the set temperature water. Of course, the condensing pipe 42 may be integrally formed with or detachable from the steam return pipe 30.

The blowing fan 44 supplies air at room temperature to the condensing pipe 42 to liquefy the steam in the condensing pipe 42.

The storage tank 46 passes the condensation pipe 42 to store the liquefied water w. Then, the water w stored in the storage tank 46 is supplied again to the heating unit 10. For this purpose, the storage tank 46 is located between the condensation pipe 42 and the heating unit 10.

The movable intermittent valve 46 is controlled by the valve control unit 50 and controls the movement of the water W stored in the storage tank 46 to the heating unit 10 by gravity. Therefore, when water W is required in the heating unit 10, the valve control unit 50 controls the water W stored in the storage tank 46 after being liquefied by opening the movable intermittent valve 48, Unit 10 as shown in FIG. For this, the condensing unit 40 is desirably provided on the upper side of the heating unit 10. When the required amount of water w in the heating unit 10 is satisfied, the valve control unit 50 controls the movable intermittent valve 46 to be closed to block the reverse movement of the steam. Of course, the water W supplied to the heating unit 10 is converted into steam by the heater 12, and then supplied to the mold m through the steam supply pipe 20.

Generally, the temperature of steam generated in the heating unit 10 is about 160 to 200 DEG C (this range may vary depending on the material of the molding and the processing form of the molding). The high-temperature steam is supplied to the injection mold m through the steam supply pipe 20. The high-temperature steam is recovered by the steam recovery pipe 30 after heating the injection mold m, and reaches a temperature of approximately 120 to 150 ° C when it reaches the condensing unit 40. The condensing unit 40 liquefies the steam in a state in which the temperature of the injection mold m is lowered to a certain extent, by about 70 to 90 ° C. The water of about 70 to 90 ° C converted into water from the steam through the condensing unit 40 is returned to the heating unit 10, whereby the waste heat recovery can be realized. Therefore, it is possible to reduce the energy required for raising the temperature of the room temperature to 70 to 90 ° C.

In summary, the heating unit 10, which generates steam, is liquefied with water containing a predetermined heat by the condensing unit 40 in which steam is recovered through the steam recovery pipe 30, The energy for generating steam in the heating unit 10 (the temperature of the water supplied from the water purifier reaches the target steam temperature and the temperature of the recovered water to the target steam temperature) Energy to reach) can be saved.

The valve control unit 50 controls opening and closing of the plurality of valves v provided on the steam supply pipe 20 and the steam return pipe 30 and the movable intermittent valve 48 constituted on the condensation unit 40 . That is, the valve control unit 50 is provided between the water purification apparatus C and the heating unit 10, the steam supply pipe 20, the steam recovery pipe 30, the condensation unit 40, the compressed air supply pipe 60, Supply of steam, recovery of steam, heating and cooling of the injection mold (m), condensation of the condensate pipe (42), and supply of the steam generated through the opening and closing control to the plurality of valves (v) And controls the movement of the medium. The supply of steam and the recovery operation of steam can be simultaneously performed through the control of the valves v and 48 by the valve control unit 50 and the supply of steam and the recovery operation of steam may be sequentially performed .

The compressed air supply pipe (60) provides a path for supplying compressed air to the injection mold (m).

The cooling water supply pipe 70 provides a path for supplying cooling water to the injection mold m. The cooling water supply pipe 70 is a pipe for supplying cooling water for cooling the injection mold m, and is distinguished from the condensing unit 40 for cooling the recovered steam.

The following is an example of the case where the supply of steam and the recovery of steam are sequentially performed.

1) Water is supplied from the water purifier C to the heating unit 10

2) The steam generated by the heating unit 10 is supplied to the injection mold m through the steam supply pipe 20

3) Steam is recovered to the condensing unit 40 through the steam recovery pipe 30 (compressed air is supplied during the recovery operation to push the residual steam in the injection mold to the steam recovery pipe)

4) Steam is condensed by condensing unit 40

5) Liquefied steam (water) containing a predetermined amount of heat is re-supplied to the heating unit 10 by gravity

The injection steam system according to the present invention can be provided with a waste heat recovering function, and the cooling water and the compressed air supplied to the injection mold (m) during the operation or before and after the operation And an operation of supplying air to the condensation pipe 42 by the discharge fan 44 and the like can be added.

As described above, the waste heat recovery system having the air-cooled condensing unit of the injection steam system according to the present invention can recover the waste heat by reusing the steam used in the processing of the injection molding to generate steam, The driving efficiency of the heating unit 10 to be generated can be increased.

Although the present invention has been fully described by way of example only with reference to the accompanying drawings, it is to be understood that the present invention is not limited thereto. It is to be understood that the scope of the invention is to be construed as being limited only by the following claims and their equivalents.

10: Heating unit
20: Steam supply piping
30: Steam recovery pipe
40: condensation unit
42: condensation piping
44: blowing fan
46: Storage tank
48: Movement intermittent valve
50: Valve control unit
60: Compressed air supply piping
70: Cooling water supply piping
w: Water purification unit
m: injection mold
v: valve

Claims (4)

A heating unit for heating water from the water purification apparatus to generate steam;
A steam supply pipe for supplying steam generated from the heating unit to an injection mold;
A steam recovery pipe for recovering the steam from the injection mold;
A condensing unit installed on the steam recovery pipe for liquefying the recovered steam; And
A valve control unit for controlling the opening and closing of a plurality of valves provided on the steam supply pipe and the steam recovery pipe; / RTI >
The condensing unit includes:
A condensing pipe connected to a part of the steam recovery pipe and having radiating fins for increasing the surface area; And
A blowing fan for supplying air to the condensing pipe to liquefy the steam inside the condensing pipe; / RTI >
The condensing unit is provided on the upper side of the heating unit so that the water liquefied by the condensing unit can be moved to the heating unit by gravity,
Wherein the water from the water purification unit is converted into steam by the heating unit and then supplied to the injection mold through the steam supply pipe, and the steam recovered from the injection mold through the steam recovery pipe is condensed Is returned to the heating unit by gravity after being liquefied in the unit with water
A waste heat recovery system having an air-cooled condensing unit of an injection steam system. The method according to claim 1,
Wherein the condensing unit lowers the temperature of the steam passing through the steam return pipe to 70 to 90 ° C to liquefy the steam
A waste heat recovery system having an air-cooled condensing unit of an injection steam system. The method according to claim 1,
A compressed air supply pipe for supplying compressed air to the injection mold; And
A cooling water supply pipe for supplying cooling water to the injection mold; Further comprising the steps < RTI ID = 0.0 >
A waste heat recovery system having an air-cooled condensing unit of an injection steam system. The method according to claim 1,
A storage tank for storing liquefied water passing through the condensing pipe, the storage tank being located between the condensing pipe and the heating unit; And
A movable intermittent valve controlled by the valve control unit and controlling the movement of water stored in the storage tank to the heating unit by gravity; ≪ RTI ID = 0.0 >
A steam supply system having a waste heat recovery function.

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