KR102277135B1 - Snow meltor by blowing hot air in vertical downward direction and driving method thereof - Google Patents

Abstract

The present invention relates to a vertical downward hot air spraying method for minimizing the loss of thermal energy required for snow melting by driving a vertical injection type burner, and to a driving method thereof, and more particularly, to air introduced from the outside After heating by using a vertical jet burner, the air heated by the burner is discharged along with the water in the form of bubbles along the cooling air pipe injection port and collection pipe to melt the snow in the melting tank. It relates to an apparatus and a method of driving the same.

Description

Snow meltor by blowing hot air in vertical downward direction and driving method thereof

The present invention relates to a vertical downward hot air spraying method for minimizing the loss of thermal energy required for snow melting by driving a vertical injection type burner, and to a driving method thereof, and more particularly, to air introduced from the outside After heating by using a vertical jet burner, the air heated by the burner is discharged along with the water in the form of bubbles along the cooling air pipe injection port and collection pipe to melt the snow in the melting tank. It relates to an apparatus and a method of driving the same.

Heavy snow refers to a weather phenomenon in which a large amount of snow falls in a short period of time. Heavy snow can cause various types of damage, such as traffic paralysis and building collapse, depending on the severity. Therefore, measures to quickly remove snow are required to prevent various damage situations such as traffic paralysis and building collapse. Generally, a method of removing snow includes a method of spraying a snow remover and a method of pushing the snow accumulated on the roadside while driving on the road. However, these methods have problems in that the environmental damage caused by the residual amount of calcium chloride on the road and the snow pushed out by the snow removal device is frozen again.

In order to solve this problem, a snow melting device that melts snow by putting it into a water tank has been developed. However, the conventional snow melting apparatus has problems in the loss of thermal energy in the melting process and the melting efficiency according to the limited capacity of the water tank.

The present invention has been devised to solve the above problems, and it is a vertical downward hot air injection method that uses a vertical injection burner to increase the efficiency of melting by minimizing the loss of thermal energy that is not used to melt snow and is wasted to the outside. An object of the present invention is to provide a snow melting apparatus and a driving method thereof.

In addition, it is an object of the present invention to provide a vertical downward hot air injection method snow melting apparatus with increased capacity of a melting tank to improve melting efficiency by minimizing the space occupied by components of the snow melting apparatus, and a driving method thereof.

In addition, it is an object of the present invention to provide a vertical downward hot air injection type snow melting apparatus and a driving method thereof, which are easy to load and work on a vehicle by reducing the weight of the components of the snow melting apparatus.

In order to achieve the above object, a burner; a hot air pipe connected to the lower end of the burner; a cooling air pipe having a structure surrounding the hot air pipe; An object of the present invention is to provide a vertical downward hot air injection method snow melting apparatus including a collecting pipe having a structure surrounding the cooling air pipe.

In addition, the cooling air pipe is to provide a vertical downward hot air injection type snow melting apparatus, characterized in that it comprises a; cooling air pipe injection port located at the end of the cooling air pipe.

In addition, the collection tube is a first outlet located at the lower end of the collection tube; A second outlet located at the upper end of the collection tube; The eaves of the plate-shaped structure located at the upper end of the second outlet; Vertical characterized in that it comprises a An object of the present invention is to provide a snow melting apparatus of a downward hot air injection method.

In addition, the cooling air pipe inlet formed at the upper end of the cooling air pipe; The hot air injection pipe inlet formed at the lower end of the hot air pipe; to provide a vertical downward hot air blowing method snow melting apparatus, characterized in that it further comprises .

In addition, it is an object of the present invention to provide a vertical downward hot air blowing method snow melting apparatus, characterized in that the inlet of the cooling air pipe is larger than the inlet of the hot air blowing pipe.

In addition, the steps of introducing air into the hot air tube inlet; heating the air introduced into the hot air tube inlet by a burner; moving the air heated by the burner to the hot air tube; to the hot air tube An object of the present invention is to provide a driving method of a vertical downward hot air injection method snow melting apparatus comprising; moving the moved air to the cooling air pipe injection port.

In addition, the step of introducing air into the cooling air pipe inlet; reducing the temperature of the hot air pipe by the air introduced into the cooling air pipe; An object of the present invention is to provide a driving method of a vertical downward hot air injection type snow melting apparatus comprising a; the step of moving the air moved to the cooling air pipe to the cooling air pipe injection port.

In addition, before the step of introducing air into the inlet of the hot air tube, the step of introducing dissolved water of a preset capacity into the melting tank; to provide a driving method of a vertical downward hot air spraying type snow melting apparatus, characterized in that it further comprises .

In addition, before the step of introducing air into the inlet of the cooling air pipe, the step of introducing dissolved water of a preset capacity into the dissolution tank; to provide a driving method of a vertical downward hot air injection type snow melting apparatus, characterized in that it further comprises do.

In addition, after the step of moving the air moved to the hot air pipe to the cooling air pipe injection port, the step of blowing air through the cooling air pipe injection port; Vertical downward hot air injection method of the snow melting apparatus characterized in that it further comprises We want to provide a driving method.

In addition, after the step of moving the air moved to the cooling air pipe to the cooling air pipe injection port, the step of blowing air through the cooling air pipe injection port; Driving of the vertical downward hot air injection method snow melting apparatus characterized in that it further comprises We want to provide a way

In addition, after the step of spraying air through the cooling air pipe injection port, the step of discharging the air of the collection pipe together with the dissolved water injected into the dissolution tank to the first discharge port and the second discharge port; characterized in that it further comprises An object of the present invention is to provide a method of driving a vertical downward hot air injection type snow melting apparatus.

In addition, there is provided a method of driving a vertical downward hot air injection type snow melting apparatus, characterized in that there is a difference between the volume of air input per unit time to the inlet of the hot air pipe and the volume of air input per unit time to the inlet of the cooling air pipe. .

In addition, the volume of air introduced into the inlet of the hot air tube is 45 cubic meters (cm³) or more and 55 cubic meters (cm³) or less per unit time, and the volume of air introduced into the inlet of the cooling air pipe is 145 cubic meters (cm³) per unit time. An object of the present invention is to provide a driving method of a vertical downward hot air injection method snow melting apparatus, characterized in that it is more than 155 cubic meters (cm³) or less. An object of the present invention is to provide a driving method of a vertical downward hot air injection method snow melting apparatus, characterized in that the unit time for air is 1 minute (60 seconds).

According to the present invention, the vertical downward hot air injection method snow melting apparatus and its driving method have the following effects.

First, there is an effect that the melting time during snow melting can be shortened by reducing the space occupied by the components of the snow melting apparatus and increasing the capacity of the melting tank.

Second, when the bubbles and dissolved water are discharged from the collecting pipe, the eaves provided at the top of the collecting pipe discharge port prevent the bubbles and dissolved water from scattering into the air, thereby reducing the loss of thermal energy.

Third, the time and movement distance of the hot air delivered from the burner to the melting tank is shortened, thereby minimizing heat loss.

Fourth, there is an effect of facilitating movement when the vehicle is loaded and operated because the weight of the components constituting the snow melting device is reduced.

Fifth, by reducing the pressure transmitted to the outlet by diversifying the outlet through which the hot air is discharged, there is an effect of reducing the noise and vibration of the equipment during operation.

Sixth, there is an effect that the temperature can be rapidly increased by diversifying the spraying directions of the discharged air and water, so that the water in the dissolution tank is uniformly sprayed inside the dissolution tank.

Seventh, the present invention has the effect of preventing the corrosion of the device by the deicing agent and calcium chloride by using a method of melting snow using the heat of the burner.

1 is a view showing the appearance of a plastic house collapsed by heavy snow.
FIG. 2 is a view showing a state in which the snow removal device installed in front of the vehicle is driven and the state of the snow removal apparatus spraying the chloride solution.
Figure 3 is a view showing the state of the snow melting apparatus.
Figure 4 is a view showing the state of the vertical downward hot air injection method snow melting apparatus according to a preferred embodiment of the present invention.
Figure 5 is a view showing a state in which the vertical downward hot air injection method snow melting apparatus of the present invention is installed in a vehicle and a truck.
Figure 6 is a view showing a view from the top of the present invention vertical downward hot air spraying method snow melting apparatus.
7 is a view showing a burner, which is a component of the vertical downward hot air injection method snow melting apparatus of the present invention.
8 is a view showing a hot air pipe and a cooling air pipe, which are components of the vertical downward hot air spraying method snow melting apparatus of the present invention.
9 is a view showing the flow of air flowing in from the cooling air pipe and the hot air pipe, which are components of the vertical downward hot air blowing method of the present invention, in the form of an arrow.
FIG. 10 is a view showing a state in which the air introduced from the inlet of the hot air injection pipe and the air introduced from the inlet of the cooling air pipe are fused and discharged from the injection port of the cooling air pipe.
11 is a view showing the components of the collecting pipe, which is a component of the vertical downward hot air spraying method snow melting apparatus according to the present invention.
12 is a view showing the flow of air bubbles moving from the cooling air pipe injection port to the collection pipe in the form of a schematic diagram.
FIG. 13 is a diagram showing the flow of bubbles moving from the collection tube to the dissolution tank in the form of a schematic diagram.
Figure 14 is a view showing the state of the dissolution tank according to a preferred embodiment of the present invention.
FIG. 15 is a diagram showing, in the form of a schematic diagram, a path through which air is introduced into the vertical downward hot air blowing method snow melting apparatus according to a preferred embodiment of the present invention.
FIG. 16 is a view showing a flow of air input to a hot air tube in the form of a flowchart according to a preferred embodiment of the present invention.
17 is a view showing a flow of air input to a cooling air pipe in the form of a flow chart according to a preferred embodiment of the present invention.
18 is a view showing the flow of air bubbles passing through the collection pipe in the form of a flow chart according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

1 is a view showing the appearance of a plastic house collapsed by heavy snow.

Heavy snow refers to a weather phenomenon in which a large amount of snow falls in a short period of time. Heavy snow sometimes causes unimaginable damage beyond the natural phenomenon of heavy snowfall. Depending on the amount of snow accumulating, it paralyzes city traffic in an instant, and facilities such as the plastic house 50 collapse due to the load of snow as shown in FIG. 1, causing a lot of damage. As the degree of damage increases according to the amount of heavy snow, rapid snow removal is required to prevent damage caused by heavy snow.

FIG. 2 is a view showing a state in which the snow removal device installed in front of the vehicle is driven and the state of the snow removal apparatus spraying the chloride solution.

Generally, as a method for quickly removing snow, a method of pushing out snow (S) accumulated while driving on a road by installing a snow plow in front of a vehicle (A), and a method of pushing snow (S) accumulated while driving on a road (A) and a method of driving a road using a snow remover or chloride solution (C) There is a method (B) for spraying on the However, in the method (A) of pushing the snow while driving on the road, there was a problem of re-freezing due to the accumulation of snow (S) in the part that did not reach the snow removal area, and the method of spraying the chloride solution (C) is the amount of the remaining amount on the road. The presence of calcium chloride could cause secondary environmental problems by corrosion of asphalt and chloride solution (C). In order to solve this problem, a snow melting apparatus 10 for dissolving snow sucked through the snow blower 40 with high heat and discharging it as dissolved water was used.

Figure 3 is a view showing the state of the conventional snow melting apparatus.

The snow melting device 10 that melts snow through the high heat sprayed from the hot air blower according to FIG. 3 does not have secondary damage due to corrosion compared to the snow removal device that sprays the snow removal agent, and compared to the snow removal device that pushes the snow removal operation There is an advantage in that there is no re-freezing problem due to residual amount in areas other than the areas where this has been performed.

As can be seen from FIG. 3 , the conventional snow removal and melting apparatus 10 is installed and used at the top of the moving means 30 for rapid melting. However, as shown in FIG. 3, the capacity of the dissolution tank 800, which is a space that substantially dissolves snow, is narrow enough to dissolve a large amount of snow because a large number of heavy equipment such as blowers, motors, and hot air tubes 300 are included in a limited space as shown in FIG. it can be seen that In addition, when the weight of the snow melting apparatus 10 installed in the moving means 30 is high, there is a problem in moving the vehicle. In addition, as shown in FIG. 3, in the conventional snow melting apparatus 10, the burner and the like are configured in a horizontal direction, and the heat energy is lost until the heated air is transferred to the snow stored in the melting tank, and eventually It caused a problem leading to a decrease in dissolution efficiency.

Figure 4 is a view showing the state of the vertical downward hot air injection method snow melting apparatus according to a preferred embodiment of the present invention.

The present inventor's vertical downward hot air blowing method snow melting apparatus 100 is a conventional snow melting apparatus 10 in a method in which air introduced from the outside is heated by a flame F generated by the burner 200 and is sprayed downward. It was designed to overcome the problems of heat energy loss in the dissolution process and the capacity of the dissolution tank.

The present inventor's vertical downward hot air injection method snow melting apparatus 100 is a burner 200, a hot air pipe 300 connected to the bottom of the burner 200, and a cooling air pipe 400 formed in a structure surrounding the hot air pipe 300. , it may be made to include a collection tube (700). In the present invention, the air introduced from the outside is heated by the burner 200 to operate in a vertical spraying manner. Accordingly, the present invention, the vertical downward hot air blowing method snow melting apparatus 100 can deliver the heated air to the melting tank 800 in a state in which the loss of thermal energy is relatively reduced compared to the conventional snow melting apparatus 10 . . While the conventional snow melting apparatus 10 introduced in FIG. 3 has a horizontal type structure such as a burner, the burner 200 of the vertical injection type snow melting apparatus 100 according to a preferred embodiment of the present invention is It can be seen that there is a big difference because it is connected to the upper end of the hot air tube 300 and the cooling air tube 400 and the air heated by the burner 200 is moved in a direct structure. In addition, the vertical downward hot air spraying method snow melting apparatus 100 may be installed inside the melting tank 800 so that the heat of the burner 200 is immediately transferred to the melting tank 800 . Therefore, the heat generated from the burner 200 can be transferred to the dissolution tank 800 as quickly as possible, and the effect of enabling an efficient dissolution operation can be expected.

Figure 5 is a view showing a state in which the vertical downward hot air injection method snow melting apparatus of the present invention is installed in a vehicle and a truck.

The vertical downward hot air injection method snow melting apparatus 100 according to the present invention forms a structure in which the air heated by the burner 200 moves vertically downward, so the size and length of the hot air tube 300 and the cooling air pipe 400 . may consist of a reduced configuration.

Accordingly, the vertical downward hot air injection method snow melting apparatus 100 according to the present invention reduces the required load compared to the conventional invention, thereby ensuring smooth movement of the moving means 30 . Accordingly, the moving means 30 installed with the vertical downward hot air spraying method snow melting apparatus 100 can move smoothly compared to the moving means 30 installed with the conventional snow melting apparatus 10 to improve the efficiency of work. possible effects can be expected.

Figure 6 is a view showing a view from the top of the present invention vertical downward hot air spraying method snow melting apparatus.

For a preferred description of the present invention, Figure 6 is a view (A) of the conventional snow melting apparatus 10 viewed from the top and a view (B) of the vertical downward hot air spraying method snow melting apparatus 100 of the present invention viewed from the upper side Let's compare and explain. In addition, FIG. 6 shows a space in which the blower pipe and other components are stored as (T).

As can be seen from (B) of FIG. 6 , it can be seen that the space T in which the blower pipe and the separate components are stored is smaller than the space T in which the blower pipe and the separate components are stored in the drawing (A). This is because components such as the burner 200, the hot air pipe 300, and the cooling air pipe 400 are provided on the upper side of the vertical downward hot air injection method snow melting apparatus 100, so that a separate space T is not required. because it doesn't Accordingly, it can be expected that the size of the dissolution tank 800, which is a space for substantially dissolving snow, becomes larger.

7 is a view showing a burner, which is a component of the vertical downward hot air injection method snow melting apparatus of the present invention.

7 is a flame (F) emitted from the burner 200 for the preferred description of the present invention is attached to the drawings will be described. A hot air injection pipe inlet 350 is formed in the hot air tube 300 according to FIG. 7 to allow air to be introduced from the outside, and the air introduced from the outside is caused by the flame F generated by the burner 200 . It can be heated while moving to the bottom. Therefore, in the present invention according to FIG. 7 , the movement time and movement distance of the air transferred from the burner 200 to the dissolution tank 800 can be shortened, so that heat loss can be reduced. Accordingly, an effect of reducing the time consumed by dissolving a large amount of snow can be expected.

In addition, since the component equipment of the vertical downward hot air injection method snow melting apparatus 100 is located at the upper end, the capacity of the melting tank 800 can be maximized, and thus the efficiency of melting can be improved. In addition, it can be expected that the effect of improving the weight installed in the moving means is easy to load.

8 is a view showing a hot air pipe and a cooling air pipe, which are components of the vertical downward hot air spraying method snow melting apparatus of the present invention.

As shown in FIG. 8 , the cooling air pipe 400 may have a structure surrounding the hot air pipe 300 . The air passing through the hot air pipe 300 of FIG. 8 is heated by the flame F after being introduced from the inlet 350 of the hot air injection pipe and hot air is transmitted in the downward direction, whereas the cooling air pipe of FIG. The air passing through 400 may be introduced from the cooling air pipe inlet 450 and the hot air may move downward in the space H between the outer surface of the hot air pipe 300 and the cooling air pipe 400 . In addition, the air passing through the cooling air pipe 400 may not rise to a hot temperature because it is not affected by the flame (F). Therefore, the air introduced from the cooling air pipe inlet 450 passes through the outer surface of the hot air tube 300 heated by the flame F to reduce the heat of the hot air tube 300, and thus the high temperature of the hot air tube 300 It has the effect of preventing safety problems caused by the condition.

There may be a difference in the volume of air per unit time introduced from the cooling air pipe inlet 450 and the hot air injection pipe inlet 350 of FIG. 8 . In the present invention, the volume of air input to the cooling air pipe inlet 450 may be introduced in a range of 145 cubic meters (cm³) or more and 155 cubic meters (cm³) or less per unit time, and the volume of air input to the hot air pipe inlet 350 is can flow in by more than 45 cubic meters (cm³) and not more than 55 cubic meters (cm³) per unit time. Accordingly, the size of the cold-steel air pipe inlet 450 may be configured to be larger than the size of the hot-air pipe inlet 350 .

9 is a view showing the flow of air flowing in from the cooling air pipe and the hot air pipe, which are components of the vertical downward hot air blowing method of the present invention, in the form of an arrow.

For the preferred description of the present invention, the flame (F) is indicated by a dotted line, the air flowing in from the hot air pipe inlet 350 (W1), the air flowing in from the cooling air pipe inlet 450 (W2), the hot air pipe ( 300) and the space between the cooling air pipe 400 is indicated by (H). As can be seen from FIG. 9 , the air introduced from the inlet of the hot air injection tube 350 may be moved to the lower end via the hot air tube 300 . In addition, since the air introduced from the cooling air pipe 400 passes through the space (H) between the outer surface of the hot air pipe 300 and the outer surface of the cooling air pipe 400, the hot air pipe 300 heated by the flame (F). It can be moved to the lower end of the cooling air pipe 400 while lowering the temperature. Thereafter, the air introduced from the cooling air pipe 400 and the air introduced from the hot air pipe 300 may be fused inside the cooling air pipe injection hole 470 to form bubbles in the water. Thereafter, the air introduced into the cooling air pipe injection hole 470 may be introduced into the dissolution tank 800 through the collection pipe 700 . The present invention according to FIG. 9 has the advantage of rapidly dissolving the snow introduced into the dissolution tank 800 by diversifying the outlets discharged to the dissolution tank 800 .

FIG. 10 is a view showing a state in which the air introduced from the inlet of the hot air injection pipe and the air introduced from the inlet of the cooling air pipe are fused and discharged from the injection port of the cooling air pipe.

(A) of FIG. 10 is a view showing a state in which the air (W1) introduced from the hot air injection pipe inlet 350 and the air (W2) introduced from the cooling air pipe inlet 450 are fused at the end of the cooling air pipe, 10 (B) is a view showing the cooling air pipe injection hole 470 formed at the end of the cooling air pipe (400).

For a preferable description of FIG. 10, FIG. 10 will be divided into (A) and (B) drawings. According to (A) of FIG. 10 , the cooling air pipe 400 may be formed to have a longer length than the hot air pipe 300 . Accordingly, a difference D between the heights of the cooling air pipe 400 and the hot air pipe 300 may exist. Due to the difference (D) in height between the cooling air pipe 400 and the hot air pipe 300, the air W1 introduced from the hot air injection pipe inlet 350 and the air W2 introduced from the cooling air pipe inlet 450 are A space S to be fused may be formed.

In addition, the air W1 introduced from the hot air injection pipe inlet 350 and the air W2 introduced from the cooling air pipe inlet 450 may be discharged in the form of bubbles. According to (B) of FIG. 10, on the outside of the space S where the air W1 introduced from the hot air injection pipe inlet 350 and the air W2 introduced from the cooling air pipe inlet 450 are fused, the cooling air pipe injection port ( 470) may be configured. Accordingly, the air W1 introduced from the hot air injection pipe inlet 350 and the air W2 introduced from the cooling air pipe inlet 450 pass through the cooling air pipe injection port 470 to the collection pipe 700 and/or the dissolution tank It may be of a configuration that is directly discharged to (800). In addition, the cooling air pipe injection hole 470 formed in the lower part of the cooling air pipe 400 allows air to be constantly and continuously discharged into the collection pipe, thereby reducing noise and vibration of the equipment and improving stability.

11 is a view showing the components of the collecting pipe, which is a component of the vertical downward hot air spraying method snow melting apparatus according to the present invention.

The collection pipe 700 according to FIG. 11 may have a cylindrical shape surrounding the cooling air pipe 400 . However, the shape of the collection tube 700 is not limited to a cylindrical shape. The collection tube 700 shown in FIG. 11 includes a first discharge port 720 located at the lower end of the collection tube 700 , a second discharge port 740 located at the upper end of the collection tube, a first discharge port 720 and a second discharge port The outlet 730 formed between the 740 and the eaves 760 of the plate-shaped structure located on the upper end of the second outlet 740 may be provided. The eaves 760 of the plate-like structure can prevent bubbles and dissolved water discharged from the second outlet 740 from scattering in the air. In addition, the eaves 760, which are components of the collection pipe 700 according to FIG. 11, directly hit the snow stored in the dissolution tank 800 when the bubbles and dissolved water are discharged from the second outlet 740, and dissolve quickly. The plate-like structure may be formed in a downward-facing shape. Accordingly, high-temperature bubbles and dissolved water are directly transferred into the dissolution tank 800 to improve the dissolution efficiency.

12 is a view showing the flow of air bubbles moving from the cooling air pipe injection port to the collection pipe in the form of a schematic diagram.

For a preferred description of the collection tube 700 according to FIG. 12 , some components included in the present invention are excluded from FIG. 12 . According to FIG. 12, the hot air moved to the cooling air pipe injection port 470 is combined with the dissolved water inside the dissolution tank 800 to form bubbles, and to be discharged through the collection pipe 700. . The bubbles discharged from the cooling air pipe injection port 470 may be moved in the upper direction and injected in the direction of the second discharge port 740 , and at the same time may be discharged in the direction of the first discharge port 720 and the jet port 730 . have. Here, when the bubbles and dissolved water are sprayed in the direction of the second outlet 740 , the eaves 760 provided at the upper end of the second outlet 740 , the hot air and the underwater air are airborne through the second outlet 740 . By discharging the released bubbles and dissolved water in the direction of the dissolution tank 800 , it may serve to prevent heat loss. In summary, the eaves 760 according to the present invention may be formed in a plate-like shape extending in the lower direction, that is, in the direction of the dissolution tank 800 , through which the bubbles discharged from the second outlet 740 . Since it can directly hit the eyes stored in the dissolution tank 800, the effect of improving the dissolution efficiency can be expected.

FIG. 13 is a diagram showing the flow of air bubbles moving from the collection tube to the dissolution tank in the form of a schematic diagram.

For a preferred description of the components of the collection tube 700, some components included in the present invention have been excluded from FIG. 13 . The collecting pipe 700, which is a component of the present invention, may be installed and driven in the dissolution tank 800.

Referring to FIG. 13 , it can be seen that the collection pipe 700 is configured to include a first outlet 720 , a second outlet 740 , and an outlet 730 . As shown in FIG. 13 , it can be seen that the directions in which bubbles are discharged from the first outlet 720 , the second outlet 740 , and the outlet 730 are different. Therefore, when snow and melted water accumulate inside the dissolution tank 800, hot air bubbles can be uniformly delivered to the snow and melted water, and the effect of improving the dissolution efficiency by inducing hot air and flow in the entire area inside the dissolution tank 800 can be expected

Figure 14 is a view showing the state of the dissolution tank according to a preferred embodiment of the present invention.

The dissolution tank 800 according to FIG. 14 may be configured to include a control device 830 and/or an opening/closing device 860 . The control device 830 according to a preferred embodiment of the present invention may be formed in a form in which the dissolved water inside the dissolution tank 800 is discharged out of the dissolution tank when it reaches a certain height or more. Therefore, it is possible to prevent the overflow phenomenon inside the dissolution tank, and there is an effect that can prevent the inhibition of the working speed due to the overflow phenomenon. In addition, dissolved water used for dissolving the eyes may be discharged through the opening/closing device 860 . The opening/closing device 860 may be configured to open and close even during a cleaning operation when the dissolution operation is completed in addition to the melting operation. The dissolution tank 800 according to FIG. 14 may be formed in a form in which a fuel tank and/or a lubricant tank are further provided in addition to the control device 830 and the opening/closing device 860 . The shape of the dissolution tank 800 according to FIG. 14 is a form expressed on the drawing for the preferred description of the present invention, and in the present invention, if it can satisfy the original function of the dissolution tank 800, it is limited to any one form may not

FIG. 15 is a view showing, in the form of a schematic view, a path through which air is introduced into the vertical downward hot air blowing method snow melting apparatus according to a preferred embodiment of the present invention.

For a preferred description of the present invention, the air introduced from the outside is divided into (W1), which is air introduced from the hot air injection pipe inlet 350, and (W2), which is air introduced from the cooling air pipe inlet 450.

According to FIG. 15, (W1) is heated by the burner 200 after it flows into the hot air injection pipe inlet 350, and (W1) heated by the burner 200 is along the hot air pipe 300. It may be vertically descended and introduced into the cooling air pipe injection port 470 .

On the other hand, after being introduced into the cooling air pipe inlet 450 , W2 may be vertically descended along the cooling air pipe 400 to be introduced into the cooling air pipe injection hole 470 . At this time, (W2) can be expected to reduce the temperature of the hot air pipe 300 heated by the burner 200 in the process of vertically descending along the cooling air pipe (400). Afterwards, (W1) and (W2) may be fused to meet inside the cooling air pipe injection hole 470, and after fusion inside the cooling air pipe injection hole 470, the collection pipe 700 and / or the dissolution tank (800) can be emitted. The bubbles and dissolved water discharged from the collection pipe 700 and/or the dissolution tank 800 may smoothly progress the dissolution process of the dissolution tank 800 .

For smooth operation of the vertical downward hot air spraying method snow melting apparatus 100 according to FIG. 15 , the driving may be performed in a state in which the melted water is injected into the melting water tank 800 . The melted water injected in advance can be heated by the vertical downward hot air spraying method snow melting apparatus 100 according to the present invention to facilitate the melting operation.

FIG. 16 is a view showing the flow of air input to a hot air tube in the form of a flowchart according to a preferred embodiment of the present invention.

After the air passing through the hot air tube 300 is introduced into the hot air injection tube inlet 350 by the blower and the external configuration (S16-1), and is heated by the flame F generated by the burner 200, (S16-2), the air heated by the flame tube may move vertically downward in the hot air tube 300 (S16-3), and then move to the cooling air tube injection port 470 (S16-4) to be sprayed. . In addition, the step of introducing dissolved water into the dissolution tank 800 and/or loading the snow inside the dissolution tank 800 before the step of introducing air into the hot air injection pipe inlet 350 (S16-1) more may be included. For reference, the volume of air input per unit time to the hot air injection pipe inlet 350 may be introduced by 45 cubic meters (cm³) or more and 55 cubic meters (cm³) or less per unit time.

45 cubic meters (cm³) or more and 55 cubic meters (cm³) per unit time is used for combustion of the burner, and the air is properly heated by the flame (F), which may be the optimal value to improve the dissolution efficiency.

17 is a view showing a flow of air input to a cooling air pipe in the form of a flow chart according to a preferred embodiment of the present invention.

The flow of air input to the cooling air pipe 400 is after the air is introduced into the cooling air pipe inlet (17-1), the temperature of the hot air pipe is reduced while moving inside the cooling air pipe 400 (S17-2), The process of moving to the cooling air pipe injection port 470 (S17-3) may be performed. Since the air introduced from the cooling air pipe inlet 450 is not affected by the burner 200 and the flame F, the temperature of the hot air pipe 300 heated by the flame F can be reduced. Accordingly, the hot air pipe 300 heated by the flame F is cooled by the air passing through the cooling air pipe 400, so that the effect of securing stability can be expected.

Thereafter, the air passing through the cooling air pipe 400 may be combined with the air passing through the hot air pipe 300 in the cooling air pipe injection port 470 to form bubbles together with the dissolved water.

18 is a view showing the flow of air bubbles passing through the collection tube in the form of a flow chart according to a preferred embodiment of the present invention.

When air bubbles are introduced into the collection pipe from the cooling air pipe injection port 470 (S18-1), they are fused in the cooling air pipe injection port 470 and then discharged to the outside, to the first discharge port 720 of the collection pipe 700 After the bubbles are discharged (S18-2), the bubbles are discharged from the outlet 730 (S18-3), and the process of discharging the bubbles to the second outlet 740 of the collection tube 700 (S18-4) is performed. can be In addition, the bubbles discharged from the first outlet 720 , the outlet 730 , and the second outlet 740 may be moved to the dissolution tank 800 to generate a convection motion ( S18 - 4 ). The flow of bubbles according to the present invention is a step in which the flow of bubbles through the collection pipe 700 is specific, and the order is not limited, and the step of discharging the bubbles to the first outlet 720 of the collection pipe 700 (S18- 2), the step of discharging air bubbles to the outlet 730 (S18-3), and the step of discharging air bubbles through the second outlet 740 of the collection pipe 700 (S18-4) are to be performed simultaneously. can Since the discharge ports are separated in both directions according to FIG. 18 , it is possible to prevent a phenomenon in which the supply of air bubbles is interrupted by the pressure of the blower pipe.

As described above, although described with reference to the first and second embodiments of the present invention, those skilled in the art will not depart from the spirit and scope of the present invention as described in the claims below. It will be understood that various modifications and variations of the present invention may be made.

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

10: Conventional snow melting apparatus
30: means of transportation
40: blower
50: plastic house
100: vertical downward hot air blowing method snow melting device
200: burner
300: hot air tube
350: hot air injection pipe inlet
400: cooling air pipe
450: cooling air pipe inlet
470: cooling air pipe nozzle
700: collection tube
720: first outlet
730: vent
740: second outlet
760: eaves
800: dissolution bath
830: adjuster
860: switchgear

Claims (18)

A burner for spraying a flame toward the bottom of the dissolution tank (burner);
a hot air tube disposed in a direction perpendicular to the bottom surface of the melting tank and connected to a lower end of the burner;
a cooling air pipe having a structure surrounding the hot air pipe;
Vertical downward hot air spraying method snow melting apparatus comprising a; collecting pipe having a structure surrounding the cooling air pipe.
According to claim 1,
The cooling air pipe is
Vertical downward hot air injection type snow melting apparatus comprising a; cooling air pipe injection port located at the lower end of the cooling air pipe.
According to claim 1,
The collection tube is
a first outlet located at the lower end of the collection tube;
a second outlet located at the upper end of the collection tube;
a spout located between the first outlet and the second outlet;
Vertical downward hot air spraying method snow melting apparatus comprising a; eaves of a plate-shaped structure located at the upper end of the second outlet.
According to claim 1,
a cooling air pipe inlet formed at an upper end of the cooling air pipe;
Vertical downward hot-air spraying method snow melting apparatus further comprising; a hot-air injection pipe inlet formed at the upper end of the hot-air tube.
5. The method of claim 4,
Vertical downward hot air injection method snow melting apparatus, characterized in that the inlet of the cooling air pipe is larger than the inlet of the hot air injection pipe.
According to claim 1,
The distance from the bottom surface of the dissolution tank to the lower end of the cooling air pipe is
Vertical downward hot air spraying method snow melting apparatus, characterized in that longer than the distance from the bottom of the melting tank to the lower end of the collection pipe.
According to claim 1,
The distance from the bottom surface of the melting tank to the lower end of the hot air tube
Vertical downward hot air spraying method snow melting apparatus, characterized in that longer than the distance from the bottom of the melting tank to the lower end of the cooling air pipe.
Step of introducing air into the inlet of the hot air injection pipe;
heating the air introduced into the hot air injection pipe inlet by a burner that sprays a flame toward the bottom surface of the dissolution tank;
moving the air heated by the burner to a hot air tube connected to a lower end of the burner;
and moving the air moved to the hot air pipe to the cooling air pipe injection port of the cooling air pipe disposed between the hot air pipe and the collection pipe.
introducing air into the inlet of the cooling air pipe;
reducing the temperature of the hot air tube heated by a burner for spraying a flame so that the air introduced into the cooling air pipe is provided inside the cooling air pipe and faces the bottom surface of the dissolution tank;
The method of driving a vertical downward hot air injection type snow melting apparatus comprising the; step of moving the air moved to the cooling air pipe surrounded by the collecting pipe to the cooling air pipe injection port.
9. The method of claim 8,
Before the step of introducing air into the inlet of the hot air injection pipe
The method of driving the vertical downward hot air spraying method snow melting apparatus, characterized in that it further comprises; adding dissolved water of a predetermined capacity to the melting tank.
10. The method of claim 9,
Before the step of introducing air into the cooling air pipe inlet
A method of driving a vertical downward hot air spraying method snow melting apparatus, characterized in that it further comprises; adding dissolved water of a predetermined capacity to the melting tank.
9. The method of claim 8,
After the step of moving the air moved to the hot air pipe to the cooling air pipe injection port of the cooling air pipe disposed between the hot air pipe and the collecting pipe
The method of driving the vertical downward hot air injection type snow melting apparatus, characterized in that it further comprises; blowing air through the cooling air pipe injection port.
10. The method of claim 9,
After the step of moving the air moved to the cooling air pipe surrounded by the collection pipe to the cooling air pipe injection port
The method of driving the vertical downward hot air injection type snow melting apparatus, characterized in that it further comprises; blowing air through the cooling air pipe injection port.
14. The method of any one of claims 12 or 13,
After the step of spraying air through the cooling air pipe injection port,
The step of discharging the air of the collection pipe together with the dissolved water injected into the dissolution tank to a first outlet, a spout, and a second outlet; a method of driving a vertical downward hot air jetting snow melting apparatus, characterized in that it further comprises.
9. The method of claim 8,
A method of driving a vertical downward hot air blowing method snow melting apparatus, characterized in that there is a difference between the volume of air input per unit time to the inlet of the hot air injection pipe and the volume of air input per unit time to the inlet of the cooling air pipe.
10. The method of claim 9,
A method of driving a vertical downward hot air spraying type snow melting apparatus, characterized in that there is a difference between the volume of air input per unit time to the inlet of the hot air injection pipe and the volume of air input per unit time to the inlet of the cooling air pipe.
17. The method of claim 15 or 16,
The volume of air introduced into the inlet of the hot air injection pipe is 45 cubic meters (cm³) or more and 55 cubic meters (cm³) or less per unit time, and the volume of air introduced into the inlet of the cooling air pipe is 145 cubic meters (cm³) or more per unit time A method of driving a vertical downward hot air blowing method snow melting device, characterized in that it is less than 155 cubic meters (cm³).
17. The method of claim 15 or 16,
A method of driving a vertical downward hot air blowing method snow melting apparatus, characterized in that the unit time for air input is 1 minute (60 seconds).

Images