KR101563170B1 - Apparatus for draining remain water of ship block for freezing prevention - Google Patents

Abstract

The present invention relates to a residual water discharging device for preventing freezing of a ship block for discharging residual water from a ship block, comprising a base portion provided on the bottom of a ship block and having a bottomed water inflow port formed therein, An ejecting portion for providing a suction force by compressed air; a residual water discharge portion connected to an upper portion of the ejecting portion and having a discharge passage for discharging residual water to the outside; and a water discharge portion provided on the outer circumference of the residual water discharge portion, And a compressed air injection unit connected to the ejecting unit for supplying compressed air to the ejecting unit. Therefore, according to the present invention, by providing the heating unit in the wastewater discharge unit, it is possible to prevent the freezing of the residual wastewater and to freeze the remaining wastewater in the wastewater discharge unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a water-

The present invention relates to an apparatus for discharging residual water of a ship block for preventing freezing, and more particularly to a system for discharging residual water from a ship block into which a storm has been introduced.

In order to build a large ship in a shipyard or shipyard in particular, it is necessary to build a block inside the ship and leave it in an outdoor workshop to carry out a preliminary design work or various other works.

In particular, ships are divided into a number of blocks when they are dried and then assembled after being manufactured. However, the ship block requires a period of time to be placed in the outdoor workplace to perform various other tasks. Foreign bodies such as water and dust may be settled in the block due to rain or the like.

Blocks are heavy in weight and large in size, making it difficult to remove residual water and foreign matter by turning over with a crane, and it is virtually impossible to remove them by the internal structure of the block. Therefore, a separate water treatment A device is needed. For example, in the past, pumps were used to remove residual water from the bottom of the block.

On the other hand, even in the case of the workplace, the number of fine lines and fine lines remains on the floor, and electric wires and various gas hoses necessary for the work are installed on the floor at the floor of the workplace. Problems can occur when you do.

In the past, a drainage channel was formed in the form of a groove so that residual water could be converged on one side of the floor of the workplace, and a method of sucking and collecting collected water using a pump was used. However, when the amount of residual water is less than a certain level, the suction power is decreased and it is difficult to completely remove the residual water.

In this case, in order to carry out subsequent processes such as welding, painting, and assembling work for the ship, it is necessary to completely remove the remaining part of the block. Therefore, since residues and foreign substances which can not be removed by the pump for removing residual water must be removed manually, And there is a problem that much effort is required. In addition, foreign matter may be mixed in the residual water of the block or the work place, which may cause malfunction or failure of the pump.

Conventionally, since the bottom surface of the workplace is formed with a paddle drainage channel and the pump for removing residual water is fixed to the floor of the workplace, residual water can be removed only at a limited position, thereby reducing the residual water removal efficiency. Further, it is difficult to provide a pump for removing residual water, and it is difficult to remove the installed pump or to move the position.

In winter, there is also a problem in that the pump for removing residual water becomes inoperable due to the freezing of residual water, the remaining water in the drain pipe is frozen and it is difficult to remove the residual water, and a separate sea ice operation has to be carried out.

Korean Registered Patent No. 10-0878427 (Jan. 13, 2009) Korean Registered Utility Model No. 20-0460495 (May 25, 2012)

Disclosure of the Invention The present invention has been devised to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus for discharging residual water of a ship block for preventing freezing, For that purpose.

It is another object of the present invention to provide a residual water discharging device for a freezing prevention vessel block capable of inserting a residual water discharge portion by an air passage and injecting warm air into an air passage to heat the discharged water discharge portion.

It is still another object of the present invention to provide a residual water discharging device for a freezing prevention vessel block which can simplify the structure of the heating section and reduce the size of the heating section to reduce the installation cost.

It is still another object of the present invention to provide a residual water discharging device for preventing freezing of a ship block which improves the heating performance of the residual water discharging portion and facilitates discharge of warmth.

It is another object of the present invention to provide a residual water discharging device for a freeze-resistant anti-freeze ship block which can be heated by compressed air without supplying power to the heating part, thereby reducing the cost of preventing icing and maintenance cost.

According to an aspect of the present invention, there is provided a device for discharging residual water from a ship block, the device comprising: a base part installed on a bottom of a ship block and having a bottom water inlet formed at a bottom thereof; An ejecting part 20 provided at an upper part of the base part 10 to provide a suction force by compressed air to discharge residual water; A residual water discharge portion 30 connected to an upper portion of the ejecting portion 20 and having a discharge passage for discharging residual water to the outside; A heating unit 40 installed on an outer periphery of the wastewater discharge unit 30 to heat the wastewater discharge unit 30 to prevent freezing of wastewater discharged through the wastewater discharge unit 30; And a compressed air injection unit (50) connected to the ejecting unit (20) and supplying compressed air to the ejecting unit (20).

The residual water discharging part (30) of the present invention comprises: a residual water discharging pipe connected to a discharging part of the ejecting part (20) and formed with a discharging passage through which residual water is discharged; And an air tube coupled around an outer periphery of the residual water discharge tube to form an air passage around the outer periphery of the residual water discharge tube.

The heating unit 40 of the present invention is composed of a vortex tube communicating with the compressed air injection unit 50 and generating warm air by the eddy of compressed air. The heating section (40) of the present invention communicates the outlet portion of the warmth to the lower end of the outer periphery of the residual water discharge section (30) to prevent freezing of residual water.

The compressed air injecting part (50) of the present invention includes: an injection pipe for supplying compressed air to the ejecting part (20); A control valve installed upstream of the injection pipe to control whether the compressed air is supplied to the ejecting unit 20 and the heating unit 40; And a branch pipe communicating with one side downstream of the injection pipe and supplying compressed air to the heating unit 40.

As described above, according to the present invention, by providing the heating unit in the wastewater discharge unit, it is possible to prevent the freezing of the residual wastewater and to freeze the remaining wastewater in the wastewater discharge unit.

In addition, since the residual water discharge portion is formed in a double pipe structure of the residual water discharge pipe and the air pipe and the air passage is formed therebetween, the residual water discharge portion is insulated by the air passage and the warm water is injected into the air passage to heat the residual water discharge portion .

In addition, by injecting the compressed air supplied to the ejecting portion so as to use the vortex tube in the heating portion, the structure of the heating portion can be simplified and the size of the heating portion can be reduced to reduce the installation cost.

Further, by supplying the warmth of the heating section from the lower part of the wastewater discharge section to the upper part, the heating performance to the wastewater discharge section is improved and the discharge of warmth is facilitated.

In addition, by supplying the compressed air to the heating unit by connecting the branch pipe to the injection pipe of the compressed air injection unit, it is possible to reduce the cost of preventing icing and maintenance cost by heating with the compressed air without supplying any additional power to the heating unit Lt; / RTI >

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a configuration diagram showing a residual water discharging device of a ship block for anti-freezing according to an embodiment of the present invention; Fig.
2 is a cross-sectional view showing a heating unit of a residual water discharging device of a ship block for anti-freezing according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view illustrating a heating unit of a residual water discharging apparatus for preventing ice formation according to an embodiment of the present invention; FIG. 2 is a cross- .

As shown in Fig. 1, the apparatus for discharging residual water of a ship block for anti-freezing according to the present embodiment includes a base portion 10, an ejecting portion 20, a residual water discharge portion 30, a heating portion 40, (50) for discharging the residual water from the ship block.

The base portion 10 is a supporting member provided on the bottom of the ship block and having a bottom water inlet formed at the lower portion thereof and includes a base 11 and a residual water inlet 12 so as to constitute a lower supporting structure of the water discharging device of this embodiment .

The base 11 is a supporting member for supporting a lower portion of the residual water discharging device and is composed of a pedestal having various shapes such as a disk or a rectangular plate and on the lower central portion of the base 11, A water inlet 12 for introducing the water to be discharged is formed.

The ejecting part 20 is provided at the upper part of the base part 10 and is provided with a housing 21, a vacuum unit 22, a nozzle unit 23, , And a compressed air inlet (24).

The housing 21 is a fixed support member which is installed on the outer circumference of the ejecting portion 20 and is fixedly coupled to the upper portion of the base portion 10. The housing 21 supports the ejecting portion 20, (10).

The vacuum unit 22 is a vacuum generating means for generating a vacuum suction force by compressed air provided from an air compressor such as a compressor separately installed outside, and generates a vacuum by a pressure difference due to the flow of compressed air.

The nozzle unit 23 is extended downstream of the vacuum unit 22 and injects the vacuum generated in the vacuum unit 22 into the residual water discharge portion 30 to suck the residual water by the suction force by the vacuum, Thereby providing a residual power to the residual water to be discharged to the outside.

The compressed air inlet 24 is a passage member provided on one side wall of the vacuum unit 22 and serves as a passage through which the compressed air provided from an air compressor such as a compressor separately provided to the outside flows into the inside of the vacuum unit 22 Respectively.

The residual water discharging portion 30 is a passage member connected to the upper portion of the ejecting portion 20 and discharging residual water to the outside. The residual water discharging portion 30 includes a residual water discharging pipe 31, an air pipe 32, an air passage 33, And a discharge port (34).

The residual water discharge pipe (31) is a piping member used as a discharge passage connected to the discharging part of the ejecting part (20) and connected to the residual water discharging part. The pipe is formed in a substantially linear shape, It is preferable that the elbow is coupled so as to be possible.

The air tube 32 is a piping member which is coupled with a predetermined distance around the periphery of the residual water discharge pipe 31 so as to form an air passage 33 around the outside of the residual water discharge pipe 31, The residual water discharge portion of the residual water discharge portion 30 is formed by the double pipe structure of the residual water discharge pipe 31 and the air pipe 32. [

The air passage (33) is a passage portion formed between the residual water discharge pipe (31) and the air pipe (32), and has an inlet port through which air flows into the lower end thereof and an outlet port through which air is discharged from the upper end thereof.

The discharge port 34 is an outlet member formed at the upper end of the residual water discharge pipe 31. A piping connection member such as a nipple or the like is provided to connect a drain pipe for discharging residual water to the outside.

The heating unit 40 heats the residual water discharging unit 30 to prevent freezing of residual water discharged through the residual water discharging unit 30 as a freezing prevention means provided on the outer periphery of the residual water discharging unit 30. [

The heating unit 40 may include a vortex tube which communicates with the compressed air injection unit 50 and generates warm air by the vortex of the compressed air. Accordingly, the heating section 40 communicates with the lower end of the outer periphery of the wastewater discharge section 30 at the outlet of the warmth from the vortex tube, thereby heating the wastewater discharge section 30 by warming, thereby preventing freezing of the wastewater .

2, the compressed air supplied to the compressed air inlet 42 of the vortex tube 41 is introduced into the rotary chamber, The primary vortex is formed while rotating at an ultra-high speed and is directed toward the high-temperature outlet 43, and a part is discharged to the outlet (30-40 ° C) by the control valve.

The remaining air that has not been discharged to the high-temperature outlet 43 is conveyed by the control valve to the secondary outlet 44 while forming a secondary vortex. At this time, the flow of the secondary vortex flows inside the flow of the primary vortex It passes through the lower pressure space and loses heat and is directed toward the low temperature outlet 44 side. In FIG. 2, the arrows marked with a double line indicate the flow of hot air and the arrows marked with a single line indicate the flow of cold air.

The temperature control of the air discharged from the high temperature outlet 43 and the low temperature outlet 44 is performed by adjusting the flow rate of the high temperature air discharged using an adjusting screw (not shown) provided on the high temperature outlet 43 side.

That is, when the flow rate of the high-temperature outlet 43 is set to a high level by using the adjusting screw, the rising width of the inflow air with respect to the temperature becomes small, while the flow rate of the low-temperature outlet 44 becomes small, .

It goes without saying that, as the heating unit 40, not only vortex tubes heated by compressed air but also electric heaters such as coils heated by electric power can be used.

The compressed air injecting portion 50 is a compressed air injecting means connected to the ejecting portion 20 and the heating portion 40 to simultaneously supply the compressed air to the ejecting portion 20 and the heating portion 40, 51, a control valve 52, a branch pipe 53, and an injection port 54.

The injection pipe 51 is a piping member for supplying compressed air to the ejecting portion 20 and is provided with a wastewater discharging portion 30 on one side of the ejecting portion 20 and an air compression And the compressed air supplied from the facility is injected into the ejector 20.

The control valve 52 is a valve member that is provided upstream of the injection pipe 51 and controls whether the compressed air is supplied to the ejecting portion 20 and the heating portion 40. The control valve 52 is connected to the lever And a ball valve for controlling the supply amount of the compressed air.

The branch pipe (53) is a piping member which is provided at one side downstream of the injection pipe (51) so as to be inclined downwardly. The compressed air supplied from an air compressor such as a compressor And supplied to the heating unit 40.

The injection port 54 is an inlet member formed at the upper end of the injection pipe 51. The injection port 54 is provided with a piping connection member such as a nipple and is provided separately from the outside, As shown in FIG.

As described above, according to the present invention, by providing the heating portion in the residual water discharge portion, it is possible to prevent freezing of the residual water released to the residual water discharge and to freeze the residual water frozen in the residual water discharge portion.

In addition, since the residual water discharge portion is formed in a double pipe structure of the residual water discharge pipe and the air pipe and the air passage is formed therebetween, the residual water discharge portion is insulated by the air passage and the warm water is injected into the air passage to heat the residual water discharge portion .

In addition, by injecting the compressed air supplied to the ejecting portion so as to use the vortex tube in the heating portion, the structure of the heating portion can be simplified and the size of the heating portion can be reduced to reduce the installation cost.

Further, by supplying the warmth of the heating section from the lower part of the wastewater discharge section to the upper part, the heating performance to the wastewater discharge section is improved and the discharge of warmth is facilitated.

In addition, by supplying the compressed air to the heating unit by connecting the branch pipe to the injection pipe of the compressed air injection unit, it is possible to reduce the cost of preventing icing and maintenance cost by heating with the compressed air without supplying any additional power to the heating unit Lt; / RTI >

The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

10: base portion 20: ejecting portion
30: Wastewater discharge unit 40: Heating unit
50: Compressed air injection unit

Claims (5)

A residual water discharging device for a ship block for discharging residual water from a ship block,
A base part 10 installed at the bottom of the ship block and having a bottom water inlet formed at the bottom thereof;
An ejecting part 20 provided at an upper part of the base part 10 to provide a suction force by compressed air to discharge residual water;
A residual water discharge portion 30 connected to an upper portion of the ejecting portion 20 and having a discharge passage for discharging residual water to the outside;
A heating unit 40 installed on an outer periphery of the wastewater discharge unit 30 to heat the wastewater discharge unit 30 to prevent freezing of wastewater discharged through the wastewater discharge unit 30; And
And a compressed air injection unit (50) connected to the ejecting unit (20) and the heating unit (40) to simultaneously supply compressed air to the ejecting unit (20) and the heating unit (40)
The heating unit 40 includes a vortex tube communicating with the compressed air injection unit 50 and generating warm air by a vortex of compressed air,
The compressed air injection unit (50)
An injection pipe for supplying compressed air to the ejecting unit 20;
A control valve installed upstream of the injection pipe to control whether the compressed air is supplied to the ejecting unit 20 and the heating unit 40; And
And a branch pipe branchably installed on one side downstream of the injection pipe so as to be inclined downwardly and to supply compressed air to the heating unit (40). The method according to claim 1,
The residual water discharge portion (30)
A residual water discharge pipe connected to a discharge part of the ejecting part 20 and formed of a discharge passage through which residual water is discharged; And
And an air pipe connected to an outer periphery of the residual water discharge pipe so as to form an air passage on an outer periphery of the residual water discharge pipe. delete The method according to claim 1,
Wherein the heating section (40) communicates with the lower end of the outer periphery of the residual water discharge section (30) to prevent freezing of residual water. delete

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