KR20200038831A - A device for clooling of around railroad - Google Patents

Abstract

Disclosed is a railroad track cooling device. According to the present invention, the railroad track cooling device includes: a cooling solution storage part (10) in which a cooling solution is stored; a high-pressure supply pump (20) forcibly sending the cooling solution in the cooling solution storage part (10) in order to spray the cooling solution supplied from the cooling solution storage part (10); a cooling solution collection part (30) including a plurality of spray nozzles (330) installed to spray the cooling solution sent by the high-pressure supply pump (20), and a storage space in which the cooling solution used by the spray nozzles (330) for cooling is stored; a circulation pump (40) returning the cooling solution stored in the cooling solution collection part (30) to the cooling solution storage part (10) in order to recirculate the cooling solution; and a remote control means (70). Therefore, the railroad track cooling device sprays the cooling solution to the periphery of a railroad switch, thereby recirculating and reusing a snow removal solution used for cooling while preventing an increase in temperature of the railroad switch.

Description

A railroad cooling system {A device for clooling of around railroad}

The present invention relates to a railroad track cooling device that can maintain the safety of railroad rails in all railroad sections or track branches, and more specifically, prevents an abnormal temperature rise by spraying a cooling solution around the railroad including the track branch. Meanwhile, the present invention relates to a railway line cooling device having a circulation supply means so that the cooling solution used for cooling can be reused.

In general, railway vehicles that are operated to move on tracks along a track are provided with turnouts and branch devices for changing the position of one vehicle from one track to another.

1 shows a plan view on a railroad of a site where a tap-off device is installed.

Referring to FIG. 1, a railway in which a turnout is installed is a train 900 for moving a vehicle on a track, a lead part B for guiding a wheel whose direction is changed by the train to a curved part, and a train. It is divided into a crossing part (C) in which the left and right wheels are completely branched.

The point portion (A) is a structure in which a normal rail is thinly cut and pressed in close contact with a basic rail to be selected by which track the railway vehicle enters from two or three tracks by the train 900, and the leading end of the blank rail is selected. Turning around the heel of the trailing edge, the train runs on the main rail as it approaches and falls off the main rail.

The lead portion (B) is a portion that is located between the point portion (A) and the crossing portion (C) to guide the train to the tongue rail.

The crossing part (C) is a part where the track line intersects each other and is composed of a V-shaped north rail and an X-shaped wing rail.

In general, rails that are always exposed to sunlight are vulnerable to poor resistance to islands, such as branching points, floating sleepers, and track-relaxing points, as rails and surrounding temperatures rise as the temperature rises in summer. Rail buckling occurs at the location.

Particularly, in the branching section, a tongue rail is mounted at the branching point of the track, and a train adjusts it to correct the trajectory of the train. When an abnormal high temperature occurs in the track, a problem arises that the track switching operation of the train is not performed well.

In order to solve this problem, when rail buckling occurs, it is necessary to perform a quick sprinkling operation on the rail to lower the temperature of the rail to lower the temperature of the rail so that it does not initially expand. Workers must carry water bottles and sprayers to hold them.

In this case, the most frequently used rail sprinkler is a sprayer with a weight of about 25-30kg on the back, and the force of the arm is used to move the compression rod up and down to compress the water, and spray the compressed water through a nozzle to spray the rail. do. Since this spraying method is sprayed about 20-30cm away from the rail when spraying, it is sprayed only on the upper surface of the rail and only a limited part is temporarily cooled, so it is inefficient to lower the temperature of the rail along with the surrounding temperature and effectively cool a wide range of parts. There are limits that cannot be. In addition, due to overwork accumulation and heat stroke of workers due to sprinkling work, and management problems in which supply and demand of workforce is difficult, along with limitations in work that depend on manpower, the efficiency of cooling work is inevitably reduced.

Accordingly, various methods of sprinkling devices have been proposed to solve the buckling phenomenon of railroad rails due to the abnormal high temperature of railroad rails and the error of operation when the railroad branch rail is operated.

As an example, the Republic of Korea Patent No. 10-0573602 line branch snow removal and cooling device is built to stand on its own on a foundation concrete that is placed on the ground adjacent to the line, the air inlet is provided to assemble one or more stacked on the upper side of the body The upper duct, the wind inlet cover coupled to the air intake of the rear part of the main body, the wind outlet provided with a plurality of air nozzles having different phase differences to eject air toward the line, and the water spray nozzle installed on the front of the main body It consists of a sprinkler that cools the heat of the rails including the tracks using the water discharged through.

In the case of such an injection method, the injection nozzle is fixed or buried in a body standing upright along the railroad periphery, and a cooling solution is sprayed at high pressure through the injection nozzle to cool the high temperature on the railroad. There is a construction problem in that construction becomes difficult due to the installation of a spray nozzle by providing a wall like this, and when the strong wind blows, the sprayed cooling solution is difficult to reach the upper part of the rail, so the sprayed cooling water is scattered or evaporates in the air. It is uneconomical and has a slight cooling effect.

Another example is spraying coolant onto a railroad while moving using a moving cart.

As an example, the Republic of Korea Patent Publication No. 10-2013-0044942 rail rail sprinkler device is connected to the support portion, the transfer wheel for transporting along the long rail on the lower surface of the support portion, and the support portion on which the cooling water storage tank is placed, A support member having a wheel support part to support a transport wheel; It is extended to the inside of the cooling water storage tank and the compression part that supplies the cooling water inside the cooling water storage tank to the outside by pumping action, and one end is connected to the compression part and the other end is connected to the transport wheel, so that the compression part operates when the transport wheel rotates. Cooling water supply member having an operation unit to let; One end is connected to the support portion of the support member, and the other end is provided with a support frame for supporting an auxiliary wheel that rotates while being in close contact with the upper surface of the pole and the other end of the extension frame extending to the other pole rail and the extension frame Extension member; A first guide frame having one end connected to the support member and extending to the upper portion of the pole rail positioned at the bottom of the support member, and one end connected to the compression part of the cooling water supply member and the other end extending to the first guide frame and having a compression part A first sprinkling member having a first sprinkling part for spraying cooling water pumped by the pole onto a long rail; One end is connected to the support frame of the extension member, one end extending to the upper part of the pole rail is connected to the compression section of the cooling water supply member, the other end is extended to the second guide frame, and the cooling water pumped by the compression section is sprayed onto the pole rail It comprises a second sprinkling member having a second sprinkling portion.

However, as it moves to a vehicle where the cooling solution storage unit in which the cooling solution is stored is installed, a lot of work force and time are required by spraying cooling water while searching for a relatively large snow section on the track, which is an uneconomical and inefficient problem.

In addition, since it cannot be used as a safety problem during the time when the vehicle is running, there is a problem in that the cooling operation is restricted because the cooling operation must be performed using a time when the vehicle is not running.

KR 10-0573602 B1 (April 18, 2006) KR 10-2013-0044942 A (2013. 05. 03.)

The present invention was invented to solve the above problems, and cooling the heat around the railroad tracks by spraying the cooling solution around the railroad tracks and the branch branches by using a high pressure injection device to be sprayed with a certain pressure or higher. The purpose is to provide a railroad cooling system that can be provided.

Another object of the present invention is to cool the railroad track and the railroad branch area by providing a means for spraying the cooling solution around the railroad line and the track branch using a high-pressure injection device and recirculating the sprayed cooling solution to be used again. It is to provide a cooling system for railroad tracks that can provide economic benefits of recycling the cooling solution.

Another object of the present invention is to prevent the temperature rise around the railway line by using a high pressure injection device to spray cooling solution to the railroad tracks and around the rail branch, and to recirculate the sprayed cooling solution to be used again. In addition, the present invention is to provide a railway line cooling device capable of automatically controlling a high-pressure supply pump and a recirculation means to further supply a cooling solution stored in a cooling solution storage unit by further comprising a sensing means capable of sensing the amount of the cooling solution.

Another object of the present invention is to use a high-pressure injection device to cool the cooling solution around the railroad tracks and the rail branches, and to provide a recirculation means to reuse the sprayed cooling solution to increase the temperature around the railroad tracks. It is to provide a railway line cooling device capable of preventing a failure of a recirculation system by removing foreign substances that may be contained in a recirculated cooling solution while preventing.

Another object of the present invention is to provide a cooling solution by using a high-pressure injection device to the railroad tracks and around the branch of the rail, and the recirculation means to recirculate the sprayed cooling solution to be used again to increase the temperature around the railroad tracks. Another object of the present invention is to provide a railway line cooling device that can further perform a task of spraying cooling solution around the railway line by automatically controlling the recirculation means at a remote site by further providing communication means. There is this.

Technical features for achieving the intended object of the present invention is an apparatus for cooling the periphery of a railway track, comprising: a cooling solution storage unit in which a cooling solution is stored; A high pressure supply pump for forcibly feeding the cooling solution in the cooling solution storage unit to spray the cooling solution supplied from the cooling solution storage unit; A cooling solution recovery unit provided with a plurality of injection nozzles for spraying the cooling solution that is pumped by the high-pressure supply pump, and having a receiving space for receiving the cooling solution used for cooling by the injection nozzle; It includes a circulation pump to return to the cooling solution storage unit for recirculating the cooling solution contained in the cooling solution recovery unit.

According to the technical features of the present invention, the cooling solution storage unit further comprises a first sensing means for confirming the dissolved state of the stored cooling solution.

According to a technical feature of the present invention, the cooling solution recovery unit further comprises a second detection means for sensing the amount of snow and the level of the cooling solution to be recovered.

According to a technical feature of the present invention, a refrigerator is installed between the high pressure supply pump and the injection nozzle to cool the cooling solution supplied from the high pressure supply pump to the cooling solution recovery unit.

According to a technical feature of the present invention, a strainer is provided between the cooling solution recovery unit and the circulation pump to remove foreign substances in the cooling solution circulated to the cooling solution storage unit.

It characterized in that it further comprises a control unit for controlling the driving of the high-pressure supply pump and the circulation pump according to the technical features of the present invention.

In accordance with the technical features of the present invention, the control unit receives signals measured from the sensing means installed in the cooling solution storage unit and the second sensing means installed in the cooling solution recovery unit, for controlling the high pressure supply pump and the circulation pump. A remote control means is further provided, wherein the remote control means is connected to a networking interface to control the control unit at a remote location, and the on-site state and the high-pressure supply pump measured by the second sensing means of the cooling solution storage unit and the cooling solution recovery unit. And remote control of a high-pressure supply pump and a circulation pump from the remote server, including a remote server that monitors a site condition of the circulation pump.

According to the technical features of the present invention, the cooling solution is water; Or frozen salts of sodium chloride (NaCl), calcium chloride (CaCl ₂ )), magnesium chloride (MgCl ₂ ), sodium sulfite (Na ₂ SO ₃ ), ethylene glycol (C ₂ H ₂ O ₂ ), propylene glycol (HOCH (CH ₃ ) CH ₂ OH) any one is selected from the aqueous solution.

According to the present invention, by providing a cooling solution by using a high-pressure injection device around the railroad track, to prevent the temperature rise around the railroad track to provide a railroad cooling system that can smoothly switch between the buckling and branching of the railroad track It has the effect.

In addition, according to the present invention, by using a high-pressure injection device, the cooling solution is sprayed around the railroad track, and a recirculation means is provided to recirculate the sprayed cooling solution so that it can be reused. It has the effect of giving the economic benefits of recycling.

In addition, according to the present invention, a cooling solution is sprayed around a railroad track by using a high-pressure injection device, and a recirculation means for recirculating the sprayed cooling solution to be used again is provided to prevent a rise in temperature around the railroad track and detect snowfall. There is an effect that can automatically control the drive of the high-pressure supply pump and recirculation means for supplying the cooling solution stored in the cooling solution storage unit by a second detection means capable of.

In addition, according to the present invention, a cooling solution is sprayed around a railroad track using a high-pressure spraying device, and a recirculation means is provided to recirculate the sprayed cooling solution so that it can be used again. There is an effect of preventing a malfunction of the recirculation system by removing foreign substances that may be contained in the recirculated cooling solution.

In addition, according to the present invention, a cooling means is sprayed around the railroad track using a high-pressure spraying device, and a recirculation means is provided to recirculate the sprayed cooling solution so that it can be used again. Further, it is possible to automatically control the recirculation means remotely from the remote management office, thereby making it easy to perform the operation of spraying the cooling solution around the railroad track.

In addition, according to the present invention, the remaining state of the cooling solution remaining in the cooling solution storage unit and the overall driving of the system for circulating the cooling solution sprayed on the cooling solution recovery unit are controlled to provide convenience of driving operation.

1 is a plan view of a railway on which a tap-off is installed
2 is a system diagram of an embodiment of the present invention
3 is a perspective view of an embodiment of the invention
Figure 4 is a front sectional view of a state in which the cooling solution installation portion of the embodiment of the present invention is installed

Features and advantages of the present invention will be more clearly understood by the embodiments described by the accompanying drawings.

Before describing the embodiments of the present invention, the application of the present invention is not limited by the configuration and arrangement of the components described in the following embodiments or illustrated in the drawings. The present invention can be implemented in other embodiments and can be performed in a variety of ways. Also, expressions and predicates used in the embodiments with respect to terms such as the direction of the device or element, etc. are only used to simplify the description of the present invention, and do not indicate or mean that the related device or element should simply have a specific direction. Does not.

Therefore, the present invention is not limited to the embodiments presented, and is within the equal scope of the technical idea of the present invention and the technical idea described in the claims to be described below by those skilled in the art to which the present invention pertains. Various modifications and changes are possible.

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

2 is a system schematic diagram of an embodiment of the present invention, FIG. 3 is a perspective view of an embodiment of the present invention, and FIG. 4 shows a front sectional view of a state in which the cooling solution installation part of the embodiment of the present invention is installed.

Referring to FIG. 1, an apparatus for cooling a railroad track periphery according to an embodiment of the present invention includes a cooling solution storage unit 10, a high pressure supply pump 20, a cooling solution recovery unit 30, a circulation pump 40, and a remote control. It comprises a control means 70.

Specifically, a cooling solution storage unit 10 in which the cooling solution is stored; A high pressure supply pump (20) for forcibly feeding the cooling solution in the cooling solution storage (10) to inject the cooling solution supplied from the cooling solution storage (10); Cooling having a plurality of injection nozzles 330 for spraying the cooling solution that is pumped by the high-pressure supply pump 20, and an accommodation space for receiving the cooling solution used for cooling by the injection nozzles 330 A solution recovery unit 30; A circulation pump 40 for returning the cooling solution contained in the cooling solution recovery unit 30 to the cooling solution storage unit 10 for recirculation; Then, the cooling solution storage unit 10, the high pressure supply pump 20, the cooling solution recovery unit 30 and the circulation pump 40 are monitored at a remote location, and the high pressure supply pump 20 and the circulation pump 40 are driven. It comprises a remote control means capable of controlling the stop.

The cooling solution storage unit 10 is made of a storage tank, and is preferably made of stainless steel or FRP system to prevent corrosion by the cooling solution, and the first sensing means for detecting the internal state ( 110) is further provided.

The cooling solution is water; Alternatively, inorganic brine and organic brine may be selectively used.

In the inorganic brine, there are aqueous solutions such as salts for refrigeration, sodium chloride (NaCl), calcium chloride (CaCl ₂ ), magnesium chloride (MgCl ₂ ), sodium sulfite (Na ₂ SO ₃ ), and ethylene glycol (C ₂ H ₂ O) in the organic brine. ₂ ), an aqueous solution such as propylene glycol (HOCH (CH ₃ ) CH ₂ OH) can be optionally used.

These brine can be used by selecting either organic or inorganic.

This brine is a medium that indirectly transports heat, circulates through the system and cools the heat around the theft by heat.

The first sensing means 110 is composed of a water level sensor 111 and a concentration sensor 112 for measuring the water level in which the cooling solution is stored in the cooling solution storage unit 10.

The water level sensor 111 detects whether the cooling solution in the cooling solution storage unit 10 is appropriate, and the concentration sensor 112 detects whether the concentration of the stored cooling solution is appropriate.

The status information of the cooling solution measured by the first sensing means 110 is transmitted to the control unit 50 and is used as an index for driving control and management of the high pressure supply pump 20 and the circulation pump 40, and the cooling solution By checking the water level, it is possible to perform replenishment of the cooling solution.

The cooling solution introduced into the cooling solution storage unit 10 may be manually input, but more preferably, it may be automatically supplied.

The high pressure pump 20 is connected to the cooling solution storage unit 10 and the first connection pipe 701, and the cooling solution in the cooling solution storage unit 10 according to the driving signal of the control unit 50, the cooling solution recovery unit By supplying the pressure at a predetermined pressure or more to the 30 to cool the heat around the railroad to the receiving portion 320.

The cooling solution recovery unit 30 is formed by a receiving portion 320 in which the cooling solution used for cooling is collected by being recessed to a certain width and depth while extending to one side from the fixed end 310 fixed to the railroad rail R. It is done.

A plurality of injection nozzles 330 are integrally formed in the fixed end portion 310 toward a direction in which the receiving portion 320 is formed in the inner space.

The cooling solution recovery unit 30 is fixed to the fixed rail 310, the rail rail (R), may be fixed by welding, it may be fixed by bolts. When the fixed end 310 is fixed with a bolt, it is possible to flexibly respond to deformation due to thermal expansion of the rail rail R.

The injection nozzle 330 is connected to the high-pressure supply pump 20 and the second connection pipe 702 in a state fixed to the railroad rail R, from the cooling solution storage unit 10 by the high-pressure supply pump 20 The supplied cooling solution is sprayed toward the accommodating part 320 to cool the heat around the railroad tracks.

The refrigerator 90 is installed in the first connection pipe 702.

The refrigerator 90 may be provided with a compressor, a condenser, a pressure reducing valve, an evaporator, etc., as in the well-known system, and has a structure of a heat pipe, or other heat exchanger (not shown), and a high pressure supply pump 20 Water or brine in the second connection pipe 702 that supplies the cooling solution from the cooling solution recovery unit 30 is cooled.

Therefore, the cooling solution injected to the injection nozzle 330 of the cooling solution recovery unit 30 is injected at a temperature lower than the normal temperature, so that the temperature around the railway can be lowered more effectively.

Preferably, the cooling solution recovery unit 30 further includes a second detection means 350 that is used for cooling around the railroad track and detects the level of the cooling solution to be recovered from the receiving unit 320.

The second detection means 350 includes an ultrasonic sensor or an infrared sensor for detecting the amount of snow, and the water level sensor 352 and the cooling solution for detecting the level of the used cooling solution. Consists of a concentration detection sensor (353) for detecting the concentration to generate a signal that can control the high-pressure supply pump 20 and the circulation pump (40).

The status information of the cooling solution recovery unit 30 measured by the second detection means 350 is transmitted to the control unit 50 as an index for driving control and management of the high pressure supply pump 20 and the circulation pump 40 It is used, and is used for cooling around the railroad track, so that the circulating recovery of the cooling solution can be performed at an appropriate time by checking the water level of the cooling solution collected in the receiving part 320.

That is, the second detection means 350 is used in the cooling solution recovery unit 30 and transmits the result of measuring the water level of the cooling solution collected in the receiving unit 320 to the control unit 50, and the control unit 50 When the cooling solution reaches the set water level input to the control unit 50, the circulation pump 40 is driven to allow the cooling solution to be recovered and recycled.

The circulation pump 40 is connected to the cooling solution recovery unit 30 by a third connection pipe 703 and is connected to a cooling solution storage unit 10 by a fourth connection pipe 704.

The circulation pump 40 enables the cooling solution used in the cooling solution recovery unit 30 to be recovered in the cooling solution storage unit 10 according to the driving signal of the control unit 50.

The third connection pipe 703 is formed with a discharge pipe 711 branching from the lower portion of the cooling solution recovery part 30, the first connection valve V1 is formed in the third connection pipe 703, and the discharge pipe ( 711) is formed with a second on-off valve (V2).

The first on-off valve (V1) and the second on-off valve (V2) may be applied to a general manual valve, an automatic opening and closing valve may be applied, it is preferable that the automatic opening and closing valve is applied for automatic control and remote control.

The first opening / closing valve V1 and the second opening / closing valve V2 perform an operation of discharging the cooling solution having a lower heat transfer solution concentration of the cooling solution from the cooling solution recovery unit 30 to the outside. Specifically, when a large amount of rainwater is mixed into the cooling solution due to rain, the concentration of the heat transfer raw material decreases, and the concentration sensor 353 detects this, and when the water level sensor 352 detects a certain level or more, the state of the cooling solution. Information is transmitted to the control unit 50. Accordingly, the control unit 50 closes the first discharge valve V1 installed in the third connection pipe 703 from the lower portion of the cooling solution recovery unit 30 and outputs an automatic control signal to open the discharge pipe 711 to recover the cooling solution. Cooling solution or water having a low concentration of the portion 30 is discharged to the outside.

Here, without the first opening / closing valve V1, the discharge pipe 711 may be installed below the cooling solution recovery unit 30 so that the second opening / closing valve V2 is installed so that drainage is performed.

The cooling solution or water with low concentration drained in this way may be drained onto the lower island of the cooling solution recovery unit 30, but may also be discharged out of the line to prevent freezing of the island.

Preferably, the third connector 703 is further provided with a strainer 60.

The strainer 60 filters the foreign substances that may be introduced into the cooling solution recovery unit 30 to prevent being sucked into the circulation pump 40, thereby maintaining the purity of the circulating cooling solution while maintaining the purity of the circulation pump 40. Prevents failure.

The control unit 50 controls the driving of the high pressure supply pump 20, the circulation pump 40, and the refrigerator 90 by receiving the measurement signals of the first detection means 110 and the second detection means 350. .

That is, it is possible to supplement the cooling solution by measuring and displaying the water level sensed by the water level sensor constituting the first sensing means 110 of the cooling solution storage unit 10.

In addition, the second detection means 350, the result of measuring the water level of the cooling solution used in the cooling solution recovery unit 30 is input and the water level collected in the receiving unit 320 by the calculated result to the control unit 50 When the input set value is reached, the circulation pump 40 is driven to allow the cooling solution to be recovered and recycled.

The cooling solution storage unit 10, the high pressure supply pump 20, the cooling solution recovery unit 30, the circulation pump 40, the control unit 50 and the freezer 90 may be formed on a moving cart 80, , It may be installed in the cab provided in the field, Figures 2 and 3 shows an example formed on the mobile carriage (80).

The moving vehicle 80 is not to move on the rail R of the railroad, but to be moved by land, and the second connecting pipe 702 and the third connecting pipe 703 can be immediately connected in a normal flange joint manner. have. Therefore, it is possible to move to a place that requires cooling of the railway track and perform cooling without limitation in train operating time.

The present invention preferably further comprises a remote control means (70).

The remote control means 70 is further configured to further include a remote server 700 and a user terminal 710 for controlling the control unit 50 at a remote location.

The remote control means 70 is connected to a networking interface to control the control unit 50 at a remote location, the first sensing means 110 of the cooling solution storage unit 10 and the second of the cooling solution recovery unit 30 Cooling solution storage unit from the remote server 700, including a remote server 700 that monitors the field condition measured by the detection means 350 and the field condition of the high pressure supply pump 20 and the circulation pump 40. 10) and the water level of the cooling solution recovery unit 30 and the high pressure supply pump 20 and the circulation pump 40, and the freezer 90 can be remotely controlled.

Then, the water level is set to be measured by the first sensing means 110 of the cooling solution storage unit 10 and the second sensing means 350 of the cooling solution recovery unit 30. It becomes possible to input in (50).

Here, the controller 50 is an A / D converter and filtering that converts analog signals measured by the first sensing means 110 and the second sensing means 350 into digital data so that the analog signals can be input and calculated by the microcomputer. Means and amplification means (not shown above) are provided and configured to transmit the calculated result to the remote server 700.

On the other hand, the remote server 700 is connected to the control unit 50 through a networking interface through a series of communication units to enable two-way communication. As described above, the control unit 50 does not perform data calculation, and the analog output from the control unit 50 An A / D converter, a filtering means, and an amplifying means (not shown above) may be provided for converting the signal into digital data so that the signal can be input and calculated by the micom.

In addition, it is provided with a peripheral device such as a central processing unit (CPU), a memory, a monitor, etc., and an input / output interface to receive and monitor signals measured by the first sensing means 110 and the second sensing means in real time.

The communication unit is an RS-232C or RS-485C using an interface converter, the control unit 50 and the remote control means 70 are connected to enable two-way communication, a central processing unit (CPU), memory, display device, It has an input / output interface that is networked with peripheral devices (not shown) such as a printer, and receives and calculates data signals transmitted from the control unit 50, displays the results, and can be output from a separate printer.

 As described above, the control unit 50 and the remote server 700 are selectively measured by the first sensing means 110 and the second sensing means 350 of the cooling solution storage unit 10 and the cooling solution recovery unit 30. It monitors the on-site condition and the on-site condition of the high pressure supply pump 20 and the circulation pump 40, and automatically controls the high pressure supply pump 20 and the circulation pump 40 remotely.

Therefore, it is possible to perform control of the system through the control unit 50 installed in the cab of the site, and also to perform remote control using a network.

The user terminal 710 is configured with, for example, a smart phone, receives a data signal output from the control unit of the remote server 700, and a program capable of controlling the high pressure supply pump 20 and the circulation pump 40. Built-in, it is possible to control the high-pressure supply pump 20 and the circulation pump 40 at a remote location.

So far, the present invention has been focused on preferred embodiments.

The embodiments described in the specification and the configuration shown in the drawings are related to one of the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, and various equivalents and modifications that can replace them It should be understood that there may be examples.

Therefore, the present invention is not limited to the embodiments presented, and is within the equal scope of the technical idea of the present invention and the technical idea described in the claims to be described below by those skilled in the art to which the present invention pertains. There may be embodiments in which various modifications and changes are possible.

10: cooling solution storage unit 110: first detection means
111: water level sensor 112: concentration sensor
20: high pressure supply pump
30: cooling solution recovery unit
330: spray nozzle 310: fixed end
320: receiving portion 330: spray nozzle
350: second detection means
40: circulation pump
50: control
60: strainer
70: remote control means 700: remote server
710: user terminal 701: first connector
702: second connector 703: third connector
704: fourth connector
80: mobile cart
90: freezer
900: Train
A: Point part B: Lead part
C: Crossing part R: Railroad rail

Claims (9)

In the device for cooling the snowfall around the railroad branch,
A cooling solution storage unit 10 in which the cooling solution is stored;
A high pressure supply pump 20 for forcibly feeding the cooling solution in the cooling solution storage unit 10 in order to spray the cooling solution supplied from the cooling solution storage unit 10;
A plurality of injection nozzles 330 for injecting the cooling solution pressure-fed by the high-pressure supply pump 20 are provided, and the receiving unit 320 for receiving the cooling solution used for cooling by the injection nozzle 330 is provided. A cooling solution recovery unit 30 provided;
Rail circulation cooling device characterized in that it comprises a circulation pump (40) for returning to the cooling solution storage unit (10) to recirculate the cooling solution contained in the cooling solution recovery unit (30).
According to claim 1,
The cooling solution storage unit 10:
Railroad track cooling device further comprises a first detection means (110) for checking the state of the stored cooling solution.
According to claim 1,
The cooling solution recovery unit 30 is:
Railroad track cooling device further comprises a second detection means (350) for sensing the water level of the cooling solution to be recovered.
According to claim 1,
A railway line cooling device comprising a strainer 60 provided between the cooling solution recovery unit 30 and the circulation pump 40 to remove foreign substances in the cooling solution circulated to the cooling solution storage unit 10.
According to claim 1,
A railroad track comprising a cooler 90 installed between the high pressure supply pump 20 and the injection nozzle 330 to cool the cooling solution supplied from the high pressure supply pump 20 to the cooling solution recovery unit 30. Cooling system.
According to claim 1,
The cooling solution,
water; Or frozen salts of sodium chloride (NaCl), calcium chloride (CaCl ₂ )), magnesium chloride (MgCl ₂ ), sodium sulfite (Na ₂ SO ₃ ), ethylene glycol (C ₂ H ₂ O ₂ ), propylene glycol (HOCH (CH ₃ ) CH ₂ OH) Railroad cooling system comprising any one selected from aqueous solutions.
According to claim 1,
Railroad track cooling device further comprises a control unit 50 for controlling the driving of the high-pressure supply pump 20 and the circulation pump (40).
The method of claim 7,
The control unit 50:
Signals measured from the first sensing means 110 installed in the cooling solution storage unit 10 and the second sensing means 350 installed in the cooling solution recovery unit 30 are input,
Railroad cooling system characterized in that it further comprises a remote control means for controlling the high-pressure supply pump (20) and the circulation pump (40).
The method of claim 8,
The remote control means,
In order to control the control unit 50 from a remote location, it is connected to a networking interface and is measured by the sensing means of the cooling solution storage unit 10 and the cooling solution recovery unit 30, and the high pressure supply pump 20 and the circulation pump Water level and high pressure supply pump 20 and circulation of the cooling solution storage unit 10 and the cooling solution storage unit 30 from the remote server 700, including the remote server 700 monitoring the on-site condition of the 40 Railroad track cooling device comprising being able to remotely control the pump (40).

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