KR101209138B1 - Agitator - Google Patents

Abstract

PURPOSE: A stirrer is provided to enhance dissolution efficiency of the deicer by agitating the deicer with water. CONSTITUTION: A stirrer(10) comprises an outer vessel(20), an inner vessel(30), a rotating unit, and a guide unit(50). The outer vessel has the accommodation space. The inner vessel is rotatably installed inside the accommodation space and has an internal space for accommodating water and deicer. A plurality of outlets(32) is prepared on the outer periphery of the inner container. The deicer is exhausted to the outer vessel by the centrifugal force generated by the rotation. The rotating unit rotates the inner vessel. The guide unit includes a guide member(51).

Description

Agitator {Agitator}

The present invention relates to an agitator, and more particularly, to an agitator for preparing snowmaking water by stirring water into which a snow removing agent such as calcium chloride or sodium chloride is added.

In general, a method for removing snow accumulated on a road in winter is to remove snow or sand such as calcium chloride, sodium chloride or magnesium chloride, and to mix them properly and scatter them on the road.

In the case of spraying snowplow or sand directly on the road, the snow removal role is quite effective, but the range of spraying is limited to the width of the vehicle passing by or the amount of antacid is scattered to the roadside and the roadside dies. Less effective or problems occurred.

In other words, when the snow remover is sprayed directly on the road, due to the limitation of the snow remover to the rotating body (spinner) of the spreader, the spreading center has a large spreading amount, the far away spraying amount is small, depending on the speed of the rotating body (spinner) There is a change in the spraying position, and if the snow removing agent coagulates due to snow (moisture), etc., the conveyor does not rotate or if a solid mass is sprayed. There is.

In addition, the consumption of time and manpower at the time of loading is large, the blowing of snow removing agent occurs according to the weather, the mass is stuck to the loading box after spraying, the washing time and washing water are large, and also sprayed with solid kernels Late reaction time, there was a variety of problems, such as a snow blower malfunction due to tangling of the snow removing agent on the rotating body (spinner).

Therefore, in order to solve such a problem, recently, a trend of spraying the snow removal solution with stirring the snow removal agent and water is changing, the spraying position of the nozzle can be adjusted by the injection by the nozzle when spraying the snow removal solution on the road surface The spraying position can be changed according to the pressure of the transfer pump, the freezing point can be adjusted according to the concentration of the aqueous solution, the washing is easy when the vehicle is painted, and the operator can work as one driver when the aqueous solution is loaded. Since it is sprayed with, there is an advantage such as a fast reaction time.

However, before spraying such a snow removal solution on the road surface, a process of making a snow removal solution by stirring the snow removal agent and water is required.

Conventional stirring apparatus includes a water supply apparatus for supplying water to the position of the stirrer, a snow removing agent input device capable of continuously feeding a snow removing agent intermittently or a small amount into the tank according to the amount of water, and water and snow removing agent It is composed of a stirring tank for storing and stirring, a stirring device provided with a propeller so as to cause a vortex of water, and a transfer device for transferring the snow removal solution to an external storage tank after stirring is completed. However, the stirring device has a disadvantage in that the propeller is damaged due to a large mass of snow removing agent or the dissolution efficiency of the snow removing agent is low due to the rotation of the propeller.

The present invention has been made to improve the above problems, the object of the present invention is to provide a stirring device that improves the dissolution efficiency of snow removal agent by rotating the inner cylinder in which the snow removal agent and water are agitated. have.

Stirring device according to the present invention for achieving the above object is provided with an outer cylinder provided with a receiving space therein, rotatably installed in the receiving space, the inner space is provided so that the water and snow removing agent is provided therein, the rotation The inner cylinder having a plurality of discharge ports provided on an outer circumferential surface of the outer circumferential surface so that the snow removing water of the snow removing agent is discharged to the outer cylinder by the centrifugal force generated at the time, and the rotating unit for rotating the inner cylinder; It is provided with a guide unit for guiding the flow of the snow removing water to be circulated to.

The inner cylinder is installed on the outer cylinder to be rotatable about a center line extending in the vertical direction, the upper surface is formed to be open, so that a flow path through which the snow removal water can flow upward between the outer peripheral surface and the outer cylinder is provided. It is formed to have an outer diameter smaller than the inner diameter of the outer cylinder, the guide unit is discharged from the inner cylinder by the centrifugal force generated during the rotation of the inner cylinder and the snow removing water rising through the flow path through the open upper surface of the inner cylinder A guide member extends in the circumferential direction on the inner wall inner wall surface of the inner cylinder upper side to guide the flow back into the inner space, and protruding in the inner cylinder direction from the inner wall surface of the outer cylinder.

The guide member is formed so as to extend from the inner wall surface of the outer cylinder so that the end portion is opposed to the upper surface of the inner cylinder, it is preferably formed inclined so as to be adjacent to the upper surface of the inner cylinder away from the inner wall surface of the outer cylinder.

On the other hand, the guide unit is formed to protrude into the inner space on the inner wall surface of the inner cylinder, the front end portion is higher than the lower end relative to the rotational direction of the inner cylinder so that the downward flow in the inner cylinder can be generated when the inner cylinder is rotated It may further include a plurality of inner protrusions formed to be inclined to the position.

In addition, the guide unit is formed on the outer circumferential surface of the inner cylinder in a direction away from the inner cylinder, the front end is lower than the lower end relative to the rotational direction of the inner cylinder so that upward flow can be generated in the flow path during the rotation of the inner cylinder It may further include a plurality of outer protrusions formed to be inclined to be located below.

The guide unit is formed to protrude in the inner cylinder direction on the inner circumferential surface of the outer cylinder corresponding to the flow path, the front end portion is rotated based on the rotational direction of the inner cylinder so that upward flow can be generated in the flow path when the inner cylinder is rotated It may further include a plurality of auxiliary protrusions formed to be inclined to be located below the end.

On the other hand, the stirring device according to the present invention is provided in the outer cylinder and the inner cylinder, the inner space is provided inside, the upper and lower surfaces are formed to be open, respectively, the snow removal water can flow between the outer peripheral surface and the inner peripheral surface of the outer cylinder upwards. An inner cylinder formed to have an outer diameter smaller than the inner diameter of the outer cylinder so that a flow path may be provided, and a forced flow part installed in the outer cylinder below the inner cylinder and flowing the snow removal water passing through the inner cylinder to the flow path; And a guide unit for guiding the flow of snow removal water so that the snow removal water introduced into the flow path by the forced flow part flows into the inner cylinder.

At this time, the guide unit is provided on the outer cylinder inner wall surface of the inner cylinder upper side to guide the snow removing water rising through the flow path by the forced flow unit to be re-introduced into the inner cylinder through the open upper surface of the inner cylinder. A guide member extends along the circumferential direction and protrudes from the inner wall surface of the outer cylinder toward the center of the inner cylinder.

The guide member is extended in a direction away from the inner wall surface of the outer cylinder so that the end portion is opposed to the upper surface of the inner cylinder, it is preferably formed to be inclined downward from the inner wall surface of the outer cylinder.

The forced flow part is rotatably installed on the bottom surface of the outer cylinder below the inner cylinder, a driving unit for rotating the rotating plate, and protrudes upward on the upper surface of the rotating plate, and extends in a direction away from the center of rotation of the rotating plate. Is provided with a plurality of stirring blades formed convexly in the rotational direction of the rotating plate to flow the snow removal water discharged downward through the open lower surface of the inner cylinder in the flow path direction.

The forced flow part further includes a plurality of crushing blades protruding upward on at least one of an upper surface of the rotating plate or an outer circumferential surface of the stirring blade to crush the snow removing agent undissolved in the snow removing water discharged from the inner cylinder. .

In addition, the stirring device according to the present invention is formed to protrude along the circumferential direction on the outer circumferential surface of the inner cylinder so as to crush the snow removal agent in the snow removal water rising along the flow path by the forced flow portion, The auxiliary blade is further provided such that the front end portion is located below the rear end portion based on the rotation direction of the rotating plate.

The stirring device according to the present invention has an advantage of improving the dissolution efficiency of the snow removing agent and reducing the occurrence of defects caused by the snow removing agent by rotating the inner cylinder into which the snow removing agent and water are agitated. .

1 is a perspective view of a stirring device according to an embodiment of the present invention,
2 is a cross-sectional view of the stirring apparatus of FIG.
3 is a perspective view of a stirring apparatus according to another embodiment of the present invention,
Figure 4 is a partial perspective view of the guide unit of the stirring device according to another embodiment of the present invention,
Figure 5 is a partial cutaway perspective view of the snow removing agent supply portion of the stirring apparatus according to another embodiment of the present invention,
Figure 6 is a partial cutaway perspective view of the washing unit of the stirring device according to another embodiment of the present invention,
7 is a perspective view of a stirring device according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail a stirring device according to a preferred embodiment of the present invention.

1 to 2 show a stirring device 10 according to an embodiment of the present invention.

Referring to the drawings, the stirring device 10 is provided with an outer cylinder 20 having a receiving space therein, rotatably installed in the receiving space, and provided with an inner space for accommodating water and snow removing agent therein, and rotating. Inner cylinder 30 having a plurality of discharge ports 32 provided on an outer circumferential surface thereof so that the snow removing the snow removing agent by the centrifugal force generated at the time can be discharged to the outer cylinder 20, and a rotating unit 40 for rotating the inner cylinder 30. ), A guide unit 50 for guiding the flow of snow removal water so that the snow removal water discharged to the outer cylinder 20 can be circulated into the inner cylinder 30, and supplying the snow removal agent to the inner cylinder 30. Snow removal supply unit (60). It is provided with a water supply unit for supplying the water to the inner cylinder (30).

The outer cylinder 20 has a receiving space therein, is formed in a cylindrical shape extending in the vertical direction, the upper surface is formed to be open so that the inner cylinder 30 can be easily installed. The outer cylinder 20 is preferably formed of stainless steel or a synthetic resin material having a predetermined strength so as to prevent the snow removing agent from being corroded by the dissolved snow removing water.

The inner cylinder 30 has an inner space therein, and is formed in a cylindrical shape extending in the vertical direction, and the upper surface of the inner cylinder 30 is opened so that the snow removing agent and water supplied from the snow removing agent 60 and the water supplying part are easily introduced into the inner space. Is formed. The inner cylinder 30 is installed inside the outer cylinder 20 to be rotatable about a center line of the head extending in the vertical direction. At this time, the inner cylinder 30 is preferably installed so that the center of rotation is located in the center of the outer cylinder (20).

The inner cylinder 30 is formed to have an outer diameter smaller than the inner diameter of the outer cylinder 20 so that a flow path 31 through which the snow removing agent can flow is provided between the outer circumferential surface and the inner circumferential surface of the outer cylinder 20. The inner cylinder 30 is preferably formed of stainless steel or a synthetic resin material having a predetermined strength to prevent the snow removal agent from being corroded by the dissolved snow removal water.

Snow removing agent and the snow-melting water dissolved in the inner cylinder 30 is discharged to the flow path 31 through the discharge port 32 by the centrifugal force generated during the rotation of the inner cylinder 30 to the flow path 31 Rises through. The snow removing agent which rises along the flow path 31 is guided by the guide unit 50 which will be described later, and reintroduced into the inner cylinder 30.

The rotary unit 40 is engaged with each other so that the driving motor 42 generates a rotational force by the power applied from the outside, and the rotational force generated from the driving motor 42 can be transmitted to the rotation shaft 41 of the inner cylinder 30. Gear box 43 is provided with a plurality of gears.

The guide unit 50 is discharged from the inner cylinder 30 by the centrifugal force generated during the rotation of the inner cylinder 30 and the snow removing water rising through the flow path 31 through the open upper surface of the inner cylinder 30 through the inner space It is provided with a guide member 51 for guiding the re-flow.

The guide member 51 extends in an annular shape along the circumferential direction on the inner wall surface of the outer cylinder 20 at a position spaced upward from the upper surface of the inner cylinder 30. The guide member 51 protrudes from the inner wall surface of the outer cylinder 20 in the direction of the inner cylinder 30 so as to easily guide the snow removal rising through the flow path 31.

At this time, the guide member 51 is formed to extend from the inner wall surface of the outer cylinder 20 so that the end portion is opposed to the upper surface of the inner cylinder 30, the farther away from the inner wall surface of the outer cylinder 20 on the upper surface of the inner cylinder 30 It is preferable to be inclined downward to be adjacent to each other.

Snow removing water discharged from the inner cylinder 30 by the centrifugal force generated when the inner cylinder 30 rotates and rises along the flow passage 31 collides with the guide member 51 formed at the upper end of the flow passage 31, The guide member 51 is guided into the inner cylinder 30 and circulated. As mentioned above, since the snow member circulates through the inner barrel 30 and the flow path 31 by the guide member 51, there is an advantage that the dissolution rate of the snow removing agent to water is improved.

The snow removal supply unit 60 is fixedly installed in a frame (not shown) at a position spaced upwardly from the inner cylinder 30 to supply the snow removal agent to the inner cylinder 30. At this time, the snow removing agent is preferably calcium chloride or sodium chloride.

The snow removing agent 60 is accommodated therein, and the lower surface of the receiving hopper 61 is provided with an outlet for discharging the snow removing agent, and is installed in the lower portion of the receiving hopper 61 to crush the snow removing agent discharged through the outlet. And a crushing portion 62 discharged to the inner cylinder 30.

The accommodation hopper 61 is provided with a storage space for accommodating the snow removing agent therein, and the outlet is formed in the center of the bottom surface. The accommodating hopper 61 is preferably formed such that its cross section becomes smaller toward the lower side so that the snow removing agent contained in the storage space through the outlet is easily discharged.

The shredding part 62 is provided with a housing 63 installed at a lower portion of the accommodation hopper 61 so as to communicate with the discharge port, and rotatably installed while being engaged with each other inside the housing 63 to remove the snow removing agent discharged through the discharge port. A plurality of shredding rollers 64 and 65 for shredding, a guide plate 66 installed at the distal end of the outlet to guide snow removal agent to the engaged position of the shredding rollers 64 and 65, and the shredding rollers 64 and 65 A driving part for driving is provided.

The housing 63 is provided with an installation space so that the shredding rollers 64 and 65 can be installed therein, and the bottom surface of the housing 63 can be easily discharged downward by the shredding rollers 64 and 65. It is formed to be open.

The shredding rollers 64 and 65 are rotatably installed at both ends in the housing 63, and although not shown in the drawing, a plurality of gear teeth are formed on the outer circumferential surface to be engaged with each other during rotation. At this time, the shredding rollers (64, 65) is preferably installed so that the mutual engagement position is opposed to the outlet.

The guide plate 66 extends from the edge of the outlet toward the center of the outlet, and is inclined downwardly away from the edge of the outlet so as to be adjacent to the interlocking positions of the shredding rollers 64 and 65.

Although not shown in the drawings, the driving unit is coupled to any one of the rotary motors that generate the rotational force by a power source applied from the outside, the first sprocket fastened to the rotary shaft of the rotary motor, and the shredding rollers 64 and 65. A second sprocket, a chain connecting the first and second sprockets, a first gear fastened to a rotation shaft of the crushing rollers 64 and 65 to which the first sprocket is fastened, and crushing rollers 64 and 65 Is coupled to the other one of the rotating shaft, and has a second gear meshed with the second gear.

A snow removing agent such as calcium chloride or sodium chloride contained in the receiving hopper 61 is introduced into the housing 63 through an outlet, which is guided by the guide plate 66 to interlock with the crushing rollers 64, 65. You are guided to. The snow removing agent introduced into the housing 63 is crushed by the crushing rollers 64 and 65 and discharged into the inner cylinder 30.

The water supply unit includes a water tank (not shown) in which water is accommodated, one end of which is in communication with the water tank, and the other end of which is provided on an upper side of the inner cylinder 30. The supply pipe 71 is formed with a discharge hole for discharging the water supplied from the water tank on the other end surface, the on-off valve is installed so that the operator can adjust the water supply amount.

On the other hand, the stirring device 10 is installed in communication with the outer cylinder 20 by the communication tube 81, the boiler 80 for heating the snow removal agent supplied from the outer cylinder 20, and the high temperature heated from the boiler 80 A storage tank 90 for receiving snow removal water is provided.

The boiler 80 collects snowmaking water produced by stirring by the rotating inner cylinder 30 and heats the collected snowmaking water. The boiler 80 burns fossil fuels such as natural gas and petroleum supplied to the outside to heat snow snow.

The storage tank 90 is provided with an inner space for accommodating the high temperature snow removal water therein, and the outer wall or the inner wall is preferably formed with a thermal insulation layer to insulate the high temperature snow removal water.

On the other hand, the operation of the stirring device 10 according to the present invention will be described in detail as follows.

First, the predetermined snow removal agent and water are supplied into the inner cylinder 30 through the snow removal supply unit 60 and the water supply unit. When the snow removing agent and water supply to the inner cylinder 30 is completed, the inner cylinder 30 is rotated through the rotating unit 40.

At this time, the snow removal agent in which the snow removing agent and water dissolved in the inner cylinder 30 are dissolved is discharged to the flow passage 31 through the discharge port 32 by the centrifugal force generated when the inner cylinder 30 is rotated, and thus the flow passage 31 To rise). The snow removing agent rising along the flow path 31 collides with the guide member 51 formed at the upper end of the flow path 31, and is guided and circulated inside the inner cylinder 30 by the guide member 51. .

As mentioned above, since the snow member circulates through the inner barrel 30 and the flow path 31 by the guide member 51, there is an advantage that the dissolution rate of the snow removing agent to water is improved.

Meanwhile, another embodiment of the guide unit 150 is shown in FIG. 3.

Elements having the same functions as those in the previous drawings are denoted by the same reference numerals.

Referring to the drawings, the guide unit 150 is formed on the inner wall surface of the inner cylinder 30, a plurality of inner protrusions 151 for generating a downward flow in the inner cylinder 30, and formed on the outer wall surface of the inner cylinder 30 It is further provided with a plurality of outer protrusions 152 for generating an upward flow in the flow path (31).

The inner protrusions 151 protrude from the inner wall surface of the inner cylinder 30 in the center direction of the inner space and extend along the circumferential direction. At this time, the inner protrusions 151 are formed to be inclined so that the front end portion is located above the lower end based on the rotation direction of the inner cylinder 30 to form a downward flow in the inner cylinder 30 during the rotation of the inner cylinder (30).

The outer protrusions 152 are formed to protrude in a direction away from the inner cylinder 30 on the outer surface of the inner cylinder 30, and extends along the circumferential direction. At this time, the outer protrusion 152 is formed to be inclined so that the front end portion is located below the lower end relative to the rotation direction of the inner cylinder 30 to form an upward flow in the flow path 31 during the rotation of the inner cylinder (30). desirable.

The inner and outer streams are generated in the inner cylinder 30 by the inner protrusions 151 and the outer protrusions 152, and a constant flow is generated in the flow path 31, so that the snow removing agent accommodated in the inner cylinder 30 and the outer cylinder 20 is provided. They are easily circulated and agitated through the inner cylinder 30 and the outer cylinder 20 by the flows of water to improve the dissolution efficiency of the snow removing agent in water. In addition, since the snow removal mass undissolved in the snow removing water is impacted and broken by the inner protrusions 151 and the outer protrusions 152, it is possible to further improve the dissolution efficiency.

On the other hand, Figure 4 shows a guide unit 250 according to another embodiment of the present invention.

Referring to the drawings, the guide unit 250 is provided with a plurality of auxiliary protrusions 251 protruding on the inner wall surface of the outer cylinder 20 to form an upward flow in the flow path (31). The auxiliary protrusions 251 are formed to protrude in a direction adjacent to the inner cylinder 30 on the inner wall surface of the outer cylinder 20 corresponding to the flow path 31, and extends along the circumferential direction. At this time, the auxiliary protrusion target 251 is preferably formed so that the front end portion is located below the lower end relative to the rotation direction of the inner cylinder 30 to form an upward flow in the flow path 31 during the rotation of the inner cylinder (30). Do.

Since an upstream water flow is generated in the flow path 31 by the auxiliary protrusions 251, the snow removing agents contained in the inner cylinder 30 and the outer cylinder 20 facilitate the inner cylinder 30 and the outer cylinder 20 by the flows. It is circulated and stirred to improve the dissolution efficiency of the snow removal agent in water. Meanwhile, in the illustrated example, only the auxiliary protrusions 251 are formed in the flow path 31, but the guide unit 250 is not limited to the illustrated example, but the auxiliary protrusions 251 and the outer protrusions are not limited to the illustrated example. 152 may all be provided in the flow path 31.

On the other hand, Figure 5 shows another embodiment of the snow removal supply unit.

Referring to the drawings, the snow removal supply unit further includes a cleaning unit 310 for removing the snow removal agent adhered to the outer peripheral surface of the crushing roller during the crushing operation of the snow removing agent.

The washing unit 310 is installed in the receiving hopper 61 in a position spaced upwardly with respect to the shredding rollers (64, 65), the washing tube 311 and the washing tube provided with a plurality of injection holes on the outer peripheral surface ( It is provided on the upper side of the 311 and the protective cover 312 to protect the cleaning tube 311 from the snow removing agent in the receiving hopper 61, and the washing water supply unit 320 for supplying the washing water to the cleaning tube (311) do.

The washing tube 311 is installed to face the engagement position of the shredding rollers 64 and 65 and extends in parallel with the longitudinal direction of the shredding roller 64. The washing tube 311 is formed in a pipe shape having a flow path through which washing water flows, and a plurality of injection holes are formed along the length direction so that the washing water is sprayed on the lower surface facing the crushing rollers 64 and 65. It is formed spaced apart.

Meanwhile, in the illustrated example, the cleaning tube 311 has been described in the housing hopper 61, but the cleaning tube 311 is not limited to the illustrated example, but the housing above the shredding rollers 64 and 65. It may also be provided at 63.

Protective cover 312 is formed to be coupled to each other a plurality of protective plates extending in parallel with the longitudinal direction of the cleaning tube. The protective plates are fixed to each other at an upper end thereof, and are fixed to be inclined so as to be farther from the lower side so that a space through which the washing tube 311 is introduced may be provided at the bottom thereof.

The washing water supply unit 320 is connected to the connection pipe 323 connected to the end of the cleaning pipe 311, the storage pipe 322 is connected to the connection pipe 323, a large amount of water is stored therein, and the connection pipe ( 323 is provided with a supply pump 321 for pumping the washing water contained in the storage tank 322 to the washing pipe (311).

The washing water contained in the storage tank 322 is pumped by the supply pump 321 and supplied to the washing tube 311, and the washing water supplied to the washing tube 311 is crushed through the plurality of injection holes (64, 65). Sprayed to remove the snow removal agent adhered to the outer peripheral surface of the shredding rollers (64, 65).

On the other hand, Figure 6 is shown a washing unit 330 according to another embodiment of the present invention.

Referring to the drawings, the shredding roller 64 is formed with a chamber (not shown) in which the washing water is received, and a plurality of ejection holes are formed on the outer circumferential surface so that the washing water may be injected. At this time, although the ejection hole is not shown in the figure, it is preferable that the gear is formed on the outer circumferential surface of the crushing roller 64 therebetween.

The washing unit 330 is formed with an injection passage (not shown) communicating with the inside of the chamber from the rotation shaft of the crushing roller 64, and is rotatably installed on the rotation shaft of the crushing roller 64 to wash water at the inlet side of the injection passage. The rotary joint 331 for supplying a, and the washing water supply unit 340 for supplying the washing water in the chamber through the rotary joint.

Although not shown in the drawing, the rotary joint 331 is formed with a groove connected to the injection passage in the circumferential direction on the outer circumferential surface of the rotation shaft of the crushing roller 64, and rotates on the rotary shaft of the crushing roller 64 to surround the groove. It is provided with a main body that is possibly installed, and a washing water supply pipe coupled to the main body for supplying the washing water to the chamber through the groove and the injection passage.

The washing water supply unit 340 is connected to the connecting pipe 343 and communicatively connected to the washing water supply pipe of the rotary joint 331 and the connecting pipe 343, and is connected to the storage tank 342 in which a large amount of washing water is received. A supply pump 341 is installed in the pipe 343 and pumps the washing water contained in the storage tank 342 into the chamber.

On the other hand, in the illustrated example, the washing unit 330 has been described in the structure installed in only one shredding roller 64, the washing unit is not limited to the illustrated example may be installed in the plurality of shredding rollers (64, 65), respectively. have.

The washing water contained in the storage tank 342 is pumped by the supply pump 341 to be supplied to the chamber inside the shredding roller 64 through the rotary joint 331, and the washing water supplied to the chamber is provided on the outer circumferential surface of the shredding roller 64. It is injected through the blowhole formed in the. The snow removing agent adhering to the outer circumferential surface of the crushing roller 64 is removed by the washing water jetted from the crushing roller 64.

On the other hand, Figure 7 is shown a stirring device 500 according to another embodiment of the present invention.

Referring to the drawings, the stirring device 500 is installed in the outer cylinder 510 and the outer cylinder 510 provided with a receiving space therein, the upper and lower surfaces are formed to be open, respectively, the outer peripheral surface and the inner peripheral surface of the outer cylinder 510 An inner cylinder 520 formed to have an outer diameter smaller than the inner diameter of the outer cylinder 510 so that the flow path 521 through which the snow removing water flows upward is provided, and the outer cylinder below the inner cylinder 520. It is installed inside the 510, the forced flow section 530 for flowing the snow removal water passing through the inner cylinder 520 to the flow path 521, and the flow path 521 by the forced flow section 530. It is provided with a guide unit 540 for guiding the flow of the snow removing water so that the snow removal flowed into the inner cylinder 520 inside.

Since the outer cylinder 510 has the same structure as the outer cylinder 20 shown in FIG. 1, a detailed description thereof will be omitted.

The inner cylinder 520 has an inner space to allow the snow removing water to pass through, and is formed in a cylindrical shape extending in the vertical direction. The inner cylinder 520 is installed at the central portion of the outer cylinder 510, and is preferably formed to have an outer diameter smaller than the inner diameter of the outer cylinder 510 so that the flow path 521 may be provided. Although not illustrated in the drawing, the inner cylinder 520 is supported by the spacer to be spaced apart from the inner wall surface of the outer cylinder 510 toward the center of the outer cylinder 510.

In addition, the lower end portion of the inner cylinder 520 is preferably formed so that the inner diameter is reduced toward the lower portion so that the snow removal water introduced into the inner cylinder 520 can pass through the lower surface of the inner cylinder 520 is easily opened.

The forced flow part 530 includes a rotating plate 531 rotatably installed on the bottom surface of the outer cylinder 510 under the inner cylinder 520, a driving unit 532 for rotating the rotating plate 531, and the rotating plate ( Protruding upward on the upper surface of the 531, extending in a direction away from the center of rotation of the rotating plate 531, the flow of snow removing the snow removal water discharged downward through the open lower surface of the inner cylinder (520) A plurality of stirring blades 534 convexly formed in the rotational direction of the rotating plate 531 and the snow removal agent undissolved in the snow removing water discharged from the inner cylinder 520 so as to flow in the It is provided with a plurality of shredding blades 535 protruding upward on the upper surface of the rotating plate 531.

The rotating plate 531 is rotatably installed on the bottom surface of the outer cylinder 510 opposite to the inner cylinder 520, and is formed in a disc shape having a predetermined radius. The driving unit 532 is a rotary motor 536 for generating a rotational force by the power applied from the outside, and a plurality of mutually engaged to transfer the rotational force generated from the rotary motor 536 to the rotating shaft of the rotating plate 531 Gear box 537 is provided with a gear.

The stirring blades 534 are formed on the upper surface of the rotating plate 531, and are formed to be spaced apart from each other along the direction of rotation of the rotating plate 531. Since the stirring blade 534 is formed to be convexly curved with respect to the rotational direction of the rotating plate 531, the snow removing water passing through the inner cylinder 520 is forced to flow toward the edge of the outer cylinder 510.

The crushing blade 535 is formed to flow upward on the upper surface of the rotating plate 531, and crushes the snow removal agent undissolved in the snow removing water discharged from the inner cylinder 520. The shredding blade 535 has both ends based on the rotational direction of the rotary plate 531 rather than the center portion so that snow removing water discharged from the inner cylinder 520 by the rotation of the rotary plate 531 can flow to the edge of the outer cylinder 510. It is preferably formed to be bent to be located rearward.

Meanwhile, in the illustrated example, the shredding blades 535 have been described on the upper surface of the rotating plate 531, but the shredding blades 535 are not limited to the illustrated example but may be formed on the outer circumferential surface of the stirring blade 534. have.

The forced flow part 530 according to the present invention configured as mentioned above forcibly flows snow removal water that has passed through the inner cylinder 520 to the edge of the outer cylinder 510, and the forced snow removal water flows into the guide unit 540. Guided and circulated to the inner cylinder 520. In addition, since the undissolved snow removing agent precipitated in the outer cylinder 510 by the rotary plate 531 installed on the bottom surface of the outer cylinder 510 has the advantage of improving the dissolution rate of the snow removing agent.

The guide unit 540 allows the snow removing water rising through the flow path 521 by the forced flow part 530 to be re-introduced into the inner cylinder 520 through the open upper surface of the inner cylinder 520. The guide member 541 extends in the circumferential direction to the inner wall surface of the outer cylinder 510 on the upper side of the inner cylinder 520, and protrudes toward the center of the inner cylinder 520 from the inner wall surface of the outer cylinder 510. And an auxiliary blade 542 protruding in the circumferential direction on the outer circumferential surface of the inner cylinder 520. Since the guide member 541 has the same structure as the guide member 51 shown in FIG. 1, a detailed description thereof will be omitted.

The auxiliary blade 542 is helically extended so that the front end portion is located below the rear end with respect to the rotation direction of the rotating plate 531. The snow removal agent undissolved in snow removal water rising along the flow path 521 by the forced flow part 530 collides with the auxiliary blade 542 and is crushed. In addition, since the auxiliary blade 542 is formed in a helical shape, the snow blades flowing in the flow path 521 are guided to easily rise.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments thereof are possible.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: stirring device
20: outer cylinder
30: inner tube
31: flow path
32: discharge port
40: rotating unit
50: guide unit
51: guide member
60: snow removal supply unit
61: hopper
62: crushed portion
80: boiler
151: medial protrusion
152: outer protrusion
251: auxiliary protrusion

Claims (15)

External passage provided with a receiving space therein;
It is rotatably installed in the receiving space, the inner space is provided to accommodate the water and the snow removing agent therein, a plurality of the outer peripheral surface so that the snow removing the snow removing agent by the centrifugal force generated during the rotation can be discharged to the outer cylinder An inner passage provided with a discharge port of;
A rotating unit for rotating the inner cylinder;
And a guide unit for guiding the flow of the snow removal water so that the snow removal water discharged to the outer cylinder can be circulated into the inner cylinder.
The method of claim 1,
The inner cylinder is installed on the outer cylinder to be rotatable about a center line extending in the vertical direction, the upper surface is formed to be open, so that a flow path through which the snow removal water can flow upward between the outer peripheral surface and the outer cylinder is provided. It is formed to have an outer diameter smaller than the inner diameter of the outer cylinder,
The guide unit
In the outer cylinder upper side of the inner cylinder to guide the snow removing water discharged from the inner cylinder by the centrifugal force generated during the rotation of the inner cylinder to rise through the flow path to be re-introduced into the inner space through the open upper surface of the inner cylinder And a guide member extending along the circumferential direction on the wall and protruding from the inner wall surface of the outer cylinder in the inner cylinder direction.
The method of claim 2,
The guide member is a stirring apparatus, characterized in that the end portion is formed extending in a direction away from the inner wall surface of the outer cylinder so as to face the upper surface of the inner cylinder, downwardly inclined from the inner wall surface of the outer cylinder.
The method of claim 2,
The guide unit
The inner wall surface of the inner cylinder is formed to protrude into the inner space, a plurality of inclined so that the front end portion is located above the lower end relative to the rotational direction of the inner cylinder so that the downward flow in the inner cylinder can be generated during the rotation of the inner cylinder. The inner projection of the; stirring apparatus characterized in that it further comprises.
The method according to claim 2 or 4,
The guide unit
On the outer circumferential surface of the inner cylinder, protruding in a direction away from the inner cylinder, the front end portion is formed to be inclined so as to be located below the lower end relative to the rotation direction of the inner cylinder so that upward flow can occur in the flow path during the rotation of the inner cylinder. Stirring apparatus further comprising; a plurality of outer protrusions.
The method according to claim 2 or 4,
The guide unit
The inner circumferential surface of the outer cylinder corresponding to the flow path is formed to protrude in the inner cylinder direction, and the front end portion is lower than the end portion based on the rotation direction of the inner cylinder so that upward flow can be generated in the flow path when the inner cylinder is rotated. Stirring apparatus further comprises; a plurality of auxiliary protrusions formed to be inclined to position.
The method of claim 1,
And a snow removal agent supply unit positioned to be spaced apart upwardly from the inner cylinder and supplying the snow removal agent to the inner cylinder.
The snow removal supply unit
A storage space is provided to accommodate the snow removal agent, and an accommodation hopper provided with a discharge port for discharging the snow removal agent downward on a lower surface thereof;
A housing installed at a lower surface of the accommodation hopper so as to communicate with the outlet, and having a lower surface opened to allow the snow removing agent discharged from the accommodation hopper to be discharged into the inner cylinder;
It is rotatably installed in the housing to crush the snow removing agent introduced into the housing and discharged into the inner cylinder, a plurality of gear teeth are provided on the outer peripheral surface to be engaged with each other, the mutually engaged position is installed to face the outlet With shredding rollers,
A driving unit for driving the crushing roller;
Stirring device comprising a washing unit for removing the snow removal agent adhered to the outer peripheral surface of the crushing roller.
The method of claim 7, wherein
The washing unit
In the interior of any one of the housing or the receiving hopper, a plurality of injection holes are provided on the outer circumferential surface facing the crushing roller to be installed at a position spaced upwardly with respect to the crushing rollers to spray the washing water to the crushing rollers A cleaning tube provided;
And a washing water supply unit for supplying the washing water to the washing tube.
The method of claim 7, wherein
At least one of the shredding rollers is formed with a chamber into which the washing water is injected, and an ejection hole for spraying the washing water to the outside is provided on an outer circumferential surface thereof.
The washing unit is formed with an injection passage communicating with the inside of the chamber from the rotation shaft of the shredding roller, rotatably installed on the rotation shaft for supplying the washing water to the inlet side of the injection passage and the rotary joint Stirring device comprising a washing water supply for supplying the washing water in the chamber through.
An outer passage provided with an accommodation space in which snow removing water is received;
The inner cylinder is installed inside the outer cylinder, the upper and lower surfaces are respectively opened, and formed to have an outer diameter smaller than the inner diameter of the outer cylinder so that a flow path through which the snow removal water can flow upward is provided between an outer circumferential surface and an inner circumferential surface of the outer cylinder. Pass;
A forced flow unit installed inside the outer cylinder below the inner cylinder and configured to flow the snow removal water that has passed through the inner cylinder into the flow path;
And a guide unit which guides the flow of the snow removing water so that the snow removing water introduced into the flow path by the forced flow part flows into the inner cylinder.
The method of claim 10,
The guide unit
Extends along the circumferential direction to the outer cylinder inner wall surface above the inner cylinder to guide the snow removing water rising through the flow path by the forced flow part to be re-introduced into the inner cylinder through the open upper surface of the inner cylinder; And a guide member protruding from the inner wall surface of the outer cylinder toward the center of the inner cylinder.
The method of claim 11,
The guide member is a stirring apparatus, characterized in that the end portion is formed extending in a direction away from the inner wall surface of the outer cylinder so as to face the upper surface of the inner cylinder, downwardly inclined from the inner wall surface of the outer cylinder.
The method according to any one of claims 10 to 12,
The forced flow part
A rotating plate rotatably installed on the bottom surface of the outer cylinder below the inner cylinder;
A drive unit for rotating the rotating plate;
The rotating plate protrudes upward on the upper surface of the rotating plate and extends in a direction away from the center of rotation of the rotating plate, so that the snow removing snow discharged downward through the open lower surface of the inner cylinder flows in the flow path direction. A stirring device comprising a; a plurality of stirring wings formed convexly in the rotational direction of the.
The method of claim 13,
The forced flow part
And a plurality of crushing blades protruding upward on at least one of an upper surface of the rotating plate or an outer circumferential surface of the stirring blade to crush the undissolved snow removing agent in the snow removing water discharged from the inner cylinder. Stirring device.
15. The method of claim 14,
Protruding in the circumferential direction on the outer circumferential surface of the inner cylinder so as to break up the snow removing agent in the snow removing water rising along the flow path by the forced flow portion, the shear based on the rotation direction of the rotating plate Auxiliary blade; further comprising; an auxiliary blade to be located below the additional rear end.

Images