KR20210121516A - Cyclone unit and road surface cleaning device having the same - Google Patents

Abstract

The present invention relates to a cyclone unit and a road surface cleaning device having the same. The cyclone unit comprises: a first unit pipe which has a first flow space formed therein and a plurality of inlets formed on the outer circumferential surface thereof so that air forcibly blown from a suction unit can enter the first flow space; a second unit pipe which is provided below the first unit pipe and has a second flow space formed therein so as to communicate with the first flow space, wherein the second flow space is formed such that the inner diameter gradually decreases toward the bottom; and flow guide parts which are installed in the inlets in order to guide the air entering the first unit pipe so that the air flowing into the first flow space flows in a spiral trajectory along the inner wall of the first unit pipe, and foreign substances can be separated therefrom. The cyclone unit and the road surface cleaning device having the same in accordance with the present invention cause the air suctioned from the suction unit to flow along the spiral trajectory and filter the foreign substances therefrom, and thus have the advantage of being able to provide relatively high cleaning efficiency even when used for a long period.

Description

Cyclone unit and road surface cleaning device having the same

The present invention relates to a cyclone unit and a road surface cleaning device having the same, and more particularly, to a cyclone unit capable of separating and collecting foreign substances contained in the air by flowing air sucked from the suction unit along a spiral track, and a cyclone unit having the same It relates to a road surface cleaning device.

In general, garbage such as fallen leaves and sand (hereinafter referred to as 'street garbage') dumped on public roads, highways, parking lots, large industrial complexes, airfield runways, large sports grounds, etc. do.

In addition, even when road garbage is removed by the road cleaning vehicle, fine dust or remnants of vehicle tires are still attached to the road surface. Such dust is scattered whenever a vehicle or the like passes and is a major cause of air pollution.

On the other hand, suction cleaning means, including a road cleaning vehicle that sucks and cleans road surface garbage, filters foreign substances in the air by passing the sucked air through the filter. There is a downside to doing it.

Laid-Open Patent Publication No. 10-2009-0063642: Cleaning apparatus for a road surface cleaning vehicle

The present invention has been devised to solve the above problems, and to provide a cyclone unit capable of separating and collecting foreign substances contained in air by flowing air sucked from a suction unit along a spiral track, and a road surface cleaning device having the same. There is a purpose.

The cyclone unit according to the present invention for achieving the above object has a first flow space formed therein, and a plurality of inlets are formed on the outer circumferential surface so that the air forcedly blown from the suction unit can be introduced into the first flow space. A unit pipe and a second unit provided under the first unit pipe, a second flow space communicating with the first flow space is formed therein, and the second flow space is formed such that the inner diameter of the second flow space decreases toward the lower side. In order to guide the air entering the pipe and the first unit pipe so that the air flowing into the first flow space flows in a spiral orbit along the inner wall of the first unit pipe to separate fine dust from the air. and a flow guide installed at the inlet.

The flow guide part is installed on the outer circumferential surface of the first unit pipe, has an induction passage communicating with the inlet, and extends a predetermined length from the inlet in the circumferential direction of the first unit pipe, and has an end of external air An induction port communicating with the guide passage is formed so that the induction port can be introduced.

Preferably, the inlet is formed in the first unit pipe to penetrate in a radial direction of the first unit pipe, and the induction port is formed in the flow guide part to penetrate in a circumferential direction of the first unit pipe.

In order to guide the air flowing into the first flow space downward along the inner wall surface of the first unit pipe, the flow guide part has a bottom surface of one end adjacent to the inlet port below the bottom surface of the other end where the induction port is provided. It may be inclined to be positioned.

The flow guide portion is formed so that the inner surface opposite to the outer circumferential surface of the first unit tube is curved with respect to the longitudinal centerline of the induction flow path so that the separation distance from the induction port to the inlet side decreases as the distance from the center of the first flow space decreases. do.

On the other hand, the cyclone unit according to the present invention is installed on the upper part of the first unit pipe so that the air rising from the second unit pipe can be discharged to the outside, and the end is introduced into the first unit pipe, the lower side of the inlet port It further includes a discharge pipe formed to be located in the.

On the other hand, the road surface cleaning device having a cyclone unit according to the present invention is provided with a main body provided with a traveling unit so as to be able to travel on the road surface in the area to be cleaned, and the main body is provided with a suction port so that foreign substances on the road surface can be introduced. A suction nozzle is formed, the loading box is installed in the main body, the loading space is provided inside so that the foreign substances introduced through the suction nozzle can be loaded, and the foreign substances on the road surface installed in the suction nozzle through the suction nozzle a suction unit that sucks in and transfers it to the loading space of the loading box; a foreign material filter unit installed in the loading box to filter foreign substances in the air sucked by the suction unit; and the foreign material filter unit connected to the foreign material filter unit A cyclone unit that separates fine dust from the air by rotating the air passing through the unit in a spiral orbit is provided.

The foreign material filter unit is installed inside the loading box, is connected to the suction unit and provided with a flow path through which the air sucked by the suction unit flows, and is installed on the flow path and introduced into the flow path. As a filter for filtering foreign substances in the air, a filter member formed to divide the flow path into an inlet section through which air is introduced from the suction unit and an outlet section through which air filtered by foreign substances is discharged, and communicates with an outlet section of the dust collecting box, and a transmission member for supplying the air that has passed through the filter member to the cyclone unit.

The foreign material filter unit may further include a collection bag detachably installed in the dust collecting box to communicate with the inlet section so as to collect the foreign material filtered by the filter member.

The transmission member has a connecting pipe connected to the dust collecting box so that one end communicates with the outlet section, and the other end of the connecting pipe, so that air passing through the connecting pipe can be introduced into the cyclone unit. and a connecting box provided with an arrangement space in which the first unit tube of the cyclone unit is installed, and the connecting tube is connected to the connecting case so that the extension direction of the other end is spaced apart from the center of the arrangement space.

The cyclone unit may further include a cyclone dust collecting filter detachably installed under the second unit pipe to collect foreign substances separated from the air.

On the other hand, the road surface cleaning apparatus having a cyclone unit according to the present invention further includes a brush unit installed in the main body portion adjacent to the suction nozzle to supply foreign substances on the road surface to the suction nozzle side, the brush unit A support frame supported on the main body adjacent to the suction nozzle by a silver support member, a rotation plate rotatably installed on the support frame, and a brush member installed on the rotation plate to interfere with foreign substances on the road surface; , a rotating part for rotating the rotating plate so that foreign substances on the road surface are introduced toward the suction nozzle.

The brush unit may further include a scattering prevention part installed on the support frame to spray the scattering prevention liquid to the road surface in order to prevent scattering of foreign substances on the road surface by the brush member.

The brush unit further includes an anti-collision part to prevent the brush member or the rotating plate from colliding with the obstacle on the road surface, and the anti-collision part includes a bracket installed on the support frame and rotatably installed on the bracket. and a protective roller whose outer peripheral surface is formed to protrude to the outside of the rotation plate.

On the other hand, the road surface cleaning apparatus having a cyclone unit according to the present invention further includes an interference unit installed in the injection nozzle in front of the suction port to interfere with foreign substances on the road surface to disperse the foreign substances fixed to each other.

The interference unit includes an interference frame installed at the front end of the suction nozzle, one end rotatably installed on the interference frame by a rotation shaft, and a first unit panel extending in a direction away from the rotation shaft; An interference member formed at the other end of the first unit panel and provided with a second unit panel extending in a direction crossing the extension direction of the first unit panel so that the end is adjacent to the road surface to interfere with foreign substances on the road surface; , an angle limiting member installed in the interference frame to interfere with the interference member so as to limit the rotation angle at which the interference member is rotated forward to a preset angle, and to the interference member so that the interference member is rotated forward An external force applying member for applying an external force is provided.

One end of the external force applying member is rotatably installed in the interference frame at a position spaced rearward with respect to the rotation axis, and the other end is the upper part of the first unit panel so as to apply an external force to the interference member by its own weight. It is formed to extend forward from the center of rotation so as to be in contact with the

The first unit panel is preferably installed on the interference frame to be movable in the vertical direction so that the space between the road surface and the interference member can be expanded.

The cyclone unit and the road surface cleaning device having the same according to the present invention have the advantage of being able to provide relatively high cleaning efficiency even when used for a long time because the air sucked from the suction unit flows along a spiral track to filter foreign substances in the air.

1 is a perspective view of a cyclone unit according to the present invention,
Figure 2 is a plan sectional view of the cyclone unit of Figure 1,
Figure 3 is a side cross-sectional view of the cyclone unit of Figure 1,
4 to 7 are simulation results using the fluid analysis program for the cyclone unit of FIG. 1,
8 is a side view of a road surface cleaning apparatus having a cyclone unit according to the present invention;
9 is a plan view of the road surface cleaning apparatus having the cyclone unit of FIG. 8;
10 is a cross-sectional view of the foreign matter filter unit of the road surface cleaning device having the cyclone unit of FIG. 8;
11 is a cross-sectional view of a cyclone unit installed in the road surface cleaning device of FIG. 8;
12 is a perspective view of an interference unit of a road surface cleaning apparatus having a cyclone unit according to another embodiment of the present invention;
13 to 15 are views illustrating an operation state of the interference unit of FIG. 12 .

Hereinafter, a cyclone unit and a road surface cleaning apparatus having the same according to an embodiment 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. In describing each figure, like reference numerals have been used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged than the actual size for clarity of the present invention.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 to 3 show a cyclone unit 10 according to the present invention.

Referring to the drawings, the cyclone unit 10 has a first flow space 21 formed therein, and an outer circumferential surface so that the air forcedly blown from the suction unit 140 can be introduced into the first flow space 21 . A first unit pipe 20 having a plurality of inlets 22 formed therein, and a second flow space ( 31) is formed, the second flow space 31 has a second unit pipe 30 that is formed to have an inner diameter that is reduced toward the lower side, and the air flowing into the first flow space 21 is discharged from the first unit pipe. A flow guide part 40 installed in the inlet 22 to guide the air introduced into the first unit pipe 20 so as to flow in a spiral path along the inner wall of the 20 and separate foreign substances from the air. ) is provided.

The first unit pipe 20 is formed in a cylindrical shape having a predetermined inner diameter so that the air introduced through the inlets 22 can flow along the spiral track. The inlets 22 are formed on the outer peripheral surface of the first unit tube 20 to be spaced apart from each other in the circumferential direction. In this case, the inlet 22 is preferably formed to penetrate in the radial direction of the first unit pipe 20 . In the illustrated example, the first unit tube 20 having six inlet ports 22 is shown, but the first unit tube 20 is not limited thereto, but five first unit tubes 20 according to the size of the first unit tube 20 . Less or more than seven inlets 22 may be formed.

A discharge pipe 224 is connected to the upper portion of the first unit pipe 20 so that air can be discharged. At this time, it is preferable that one end of the discharge pipe 224 is installed to be drawn into the inside of the first unit pipe 20 by a predetermined depth.

The discharge pipe 224 is connected to the upper part of the first unit pipe 20 , and one end is installed to be drawn into the inside of the first unit pipe 20 by a predetermined depth. In this case, one end of the discharge pipe 224 has an outer diameter smaller than the inner diameter of the first unit pipe 20 , and extends downward a predetermined length with respect to the upper surface of the first unit pipe 20 . Here, the discharge pipe 224 is formed to extend downward so that one end is located below the inlet 22, and the other end is formed to be open so that air is discharged to the outside.

The second unit pipe 30 is connected to the lower portion of the first unit pipe 20 , and a second flow space 31 communicating with the first flow space 21 is formed therein. The second unit pipe 30 is formed in a conical shape with an inner diameter decreasing toward the lower part so that the air introduced through the first unit pipe 20 can rise to the upper part having a relatively lower pressure than the lower part.

As the air introduced into the first and second unit pipes 20 and 30 rotates in a spiral orbit in the first and second flow spaces 31, foreign substances having a predetermined weight fall downward, and the second unit pipe ( 30) is preferably formed so that the lower part is opened so that the falling foreign material can be discharged to the outside.

A plurality of flow guide parts 40 are installed on the outer circumferential surface of the first unit pipe 20 so as to communicate with the inlets 22 , respectively. The flow guide part 40 has an induction passage 41 communicating with the inlet 22 , and extends from the inlet 22 by a predetermined length in the circumferential direction of the first unit tube 20 . In addition, the flow guide part 40 has an induction port 42 that communicates with the guide passage 41 so that external air can be introduced at an end thereof. At this time, it is preferable that the plurality of flow guide parts 40 are formed so that the extending directions from the inlet 22 are the same.

At this time, the induction port 42 is formed in the flow guide part 40 to penetrate along the circumferential direction of the first unit pipe 20 . In addition, the flow guide part 40 has a bottom surface at one end adjacent to the inlet 22 to guide the air flowing into the first flow space 21 downward along the inner wall surface of the first unit pipe 20 . It is inclined so as to be located below the bottom surface of the other end on which the induction part is provided. That is, the bottom surface of the flow guide part 40 is inclined downward from the induction port 42 toward the inlet 22 of the first unit pipe 20 .

In addition, the flow guide part 40 is formed to be curved so that the inner surface opposite to the outer peripheral surface of the first unit tube 20 has a predetermined curvature based on the longitudinal centerline of the guide passage 41 . That is, the inner surface of the flow guide part 40 is formed to be curved so that the separation distance from the induction port 42 to the inlet 22 side toward the center of the first flow space 21 decreases.

Meanwhile, results of simulations performed using a fluid analysis program for the above-described cyclone unit 10 are shown in FIGS. 4 to 7 . 4 and 5 are simulation results of a state in which air is introduced into the cyclone unit 10 at a flow rate of 15 m/s, and FIGS. state simulation result.

Referring to the drawings, when air is introduced into the cyclone unit 10 at a flow rate of 15 m/s, the average flow rate of the air discharged from the cyclone unit 10 is 19.77 m/s, and the discharge air volume is 20.32 CMM per minute (m). ³ /min). Since the inflow air volume is 21.4 CMM (m ³ /min), the discharge capacity of the magnetic air volume of the cyclone unit 10 is about 94.95%. In addition, it can be seen that the air flow at the upper end of the cyclone unit 10 is smoothly introduced into the six inlets 22, and the air moves to the bottom while the cyclone swirl flow rotates clockwise. It can be seen that particle separation is possible. In addition, it can be seen that the air discharged from the cyclone unit 10 is discharged while the cyclone swirl flow rotates counterclockwise, and it can be seen that fine particles can be discharged.

In addition, when air is introduced into the cyclone unit 10 at a flow rate of 20 m/s, the average flow rate of the air discharged from the cyclone unit 10 is 27.16 m/s, and the discharge air volume is 27.16 CMM per minute (m ³ /min) )am. Since the inflow air volume is 28.5 CMM (m ³ /min), the discharge capacity of the magnetic air volume of the cyclone unit 10 is about 95.30%. In addition, it can be seen that the air flow at the upper end of the cyclone unit 10 is smoothly introduced into the six inlets 22, and the air moves to the bottom while the cyclone swirl flow rotates clockwise. It can be seen that particle separation is possible. In addition, it can be seen that the air discharged from the cyclone unit 10 is discharged while the cyclone swirl flow rotates counterclockwise, and it can be seen that fine particles can be discharged.

On the other hand, although not shown in the drawing, the cyclone unit 10 according to the present invention further includes an air filtering unit installed in the first unit pipe 20 to filter foreign substances in the air flowing into the flow guide unit 40 . You may.

The air filtering unit includes a first flange member protruding radially from the first unit pipe 20 above the flow guide unit 40 and extending in the circumferential direction, and the flow guide unit 40 below the flow guide unit 40 . A second flange member protruding in the radial direction and extending in the circumferential direction in the first unit pipe 20 is formed to cover the space between the first and second flange members, and air is passed through , it is provided with a filter network in which a plurality of filtering holes are formed so that foreign substances in the air can be filtered out.

The first flange member is formed to protrude from the outer circumferential surface of the first unit pipe 20 , and extends in an annular shape along the circumferential direction of the first unit pipe 20 . At this time, the first flange member is formed such that the protruding length of the first unit pipe 20 with respect to the outer surface is greater than the protruding length of the flow guide part 40 with respect to the outer surface of the first unit pipe 20 . it is preferable

The second flange member is formed to protrude from the outer circumferential surface of the second unit pipe 30 , and extends in an annular shape along the circumferential direction of the first unit pipe 20 . In this case, the second flange member is formed such that the protruding length of the first unit pipe 20 with respect to the outer surface is greater than the protruding length of the flow guide part 40 with respect to the outer surface of the first unit pipe 20 . it is preferable

The upper and lower portions of the filter net are respectively fixed to the edges of the first and second flange members, respectively, and extend in an annular shape along the first and second flange members. The filter net is formed with a plurality of filtering holes, it is preferable to be formed of a metallic material. Foreign substances having a relatively large volume among the air introduced from the suction unit 140 may be filtered through the corresponding filter network.

On the other hand, the road surface cleaning apparatus 100 having a cyclone unit according to the present invention is shown in FIGS. 8 to 11 .

Referring to the drawings, the road surface cleaning apparatus 100 having the cyclone unit includes a main body 110 provided with a traveling unit so as to travel on a road surface in an area to be cleaned, and the main body 110 is provided on the road surface. A suction nozzle 120 with a suction port formed so that foreign substances can be introduced, and a loading box provided with a loading space inside so that the suction nozzle 120 is installed and the foreign material introduced through the suction nozzle 120 can be loaded The sieve 130 and the suction unit 140 installed in the suction nozzle 120 to suck the foreign material on the road surface through the suction nozzle 120 and transfer it to the loading space of the loading box 130; A foreign material filter unit 200 installed in the loading box 130 to filter foreign substances in the air sucked by the suction unit 140, and the foreign material filter unit 200 connected to the foreign material filter unit 200 A cyclone unit 10 for separating fine dust from the air is provided by rotating the passed air in a spiral orbit. Here, since the cyclone unit 10 is the same as the aforementioned cyclone unit 10, a detailed description thereof will be omitted.

The main body 110 is provided with a plurality of front wheels 111 in the front lower portion and a plurality of rear wheels 112 in the rear lower portion. Here, the front wheel 111 provided in front of the main body 110 is driven by the driving unit. Although not shown in the drawings, the driving unit includes a driving motor installed on the front wheel 111 to rotate the front wheel 111 and a battery for supplying power to the driving motor.

In addition, the main body 110 is further provided with a steering means (not shown) for steering the rear wheels 112, the steering means as such is that the operator steers the driving direction of the main body 110, Since it is a steering device generally used in the prior art, a detailed description thereof will be omitted.

In addition, a boarding member 113 is provided at the rear of the main body 110 so that the operator can board in an upright state. The operator rides on the boarding member 113 and moves, steers the main body 110 or controls the suction unit 140 , and the like.

The suction nozzle 120 is installed on the front end of the main body 110, the suction port is formed on the lower surface. At this time, the suction nozzle 120 is preferably installed in the body portion 110 at a position spaced upward by a predetermined distance with respect to the road surface. At this time, the suction nozzle 120 is installed at the rear of the suction port, and the auxiliary panel 121 is installed. The auxiliary panel 121 protrudes downward from the suction nozzle 120 so that the lower end thereof is adjacent to the road surface in order to prevent foreign substances on the road surface from passing through the suction nozzle 120, and it is preferable to extend in an arc shape around the suction port. do.

The loading box 130 is installed in the upper portion of the main body 110 at a position spaced rearward with respect to the suction nozzle 120, and is formed in a rectangular structure having a loading space therein. In addition, although not shown in the drawing, the loading box 130 is formed to have an open side, and a cover member is installed to open and close the open side. In addition, a plurality of outlet holes may be formed on the lower surface of the loading box 130 so that air can be discharged to the outside.

The suction unit 140 provides suction force to the suction nozzle 120 , and includes a first suction pipe 141 , a suction housing 142 , a second suction pipe 143 , a blower fan 144 , and a driving motor 145 . be prepared

One end of the first suction pipe 141 is connected to the suction nozzle 120 , and a flow path is formed therein so that air sucked through the suction nozzle 120 can flow. A suction housing 142 is installed at the other end of the first suction pipe 141 .

The suction housing 142 is provided with an installation space therein so that the blowing fan 144 can be installed, and the other end of the first suction pipe 141 is connected in communication. The suction housing 142 is preferably installed in the body portion 110 at a position adjacent to the suction nozzle 120 .

The second suction pipe 143 has one end connected in communication with the suction housing 142 and the other end connected in communication with the loading box 130 . Here, the second suction pipe 143 is formed with a flow path so that air can flow therein. In addition, the second suction pipe 143 is preferably connected to the other end of the upper surface of the front side of the loading box (130).

The blowing fan 144 is rotatably installed inside the suction housing 142 . Since the blower fan 144 is a fan generally used in the prior art to forcibly blow air during rotation, a detailed description thereof will be omitted. The driving motor 145 is installed on the blowing fan 144 to rotate the corresponding blowing fan 144 to generate a suction force. According to the rotation of the blowing fan 144 , foreign substances on the road surface are sucked together with air through the suction nozzle 120 , pass through the suction housing 142 , and then injected into the loading box 130 . At this time, the foreign substances introduced into the suction housing 142 are crushed by the high-speed rotating blower fan 144 and injected into the loading box 130 .

The foreign material filter unit 200 is installed inside the loading box 130 , and is connected to the suction unit 140 , and a dust collecting box 210 provided with a flow path through which the air sucked by the suction unit 140 flows. ), installed on the flow path to filter foreign substances in the air introduced into the flow path, and an inlet section 221 through which air is introduced from the suction unit 140 through the flow path, and air from which foreign substances are filtered The filter member 220 formed to partition into the outlet section 222 through which is discharged is communicated with the outlet section 222 of the dust collecting box 210, and the air passing through the filter member 220 is transferred to the cyclone unit. A collection bag 240 detachably installed in the dust collecting box 210 so as to communicate with the inlet section 221 so as to collect the supplied transfer member 230 and the foreign substances filtered by the filter member 220 . ) is provided.

The dust collecting box 210 is installed inside the loading box 130 , and a communication hole 211 is formed at the upper portion to communicate with the second suction pipe 143 of the suction unit 140 . In addition, the dust collecting box 210 is provided with a flow path in which the filter member 220 is installed.

The filter member 220 divides the flow path of the dust collecting box 210 into an inlet section 221 communicating with the second suction pipe 143 and an outlet section 222 communicating with the transmission member 230, the filter box 223 and an auxiliary filter 224 .

The filter box 223 is provided with a communication space communicating with the communication port 211 of the dust collecting box 210 therein so as to be connected to the second suction pipe 143 . In addition, the filter box 223 is formed to have a vertical width corresponding to the vertical width of the flow path of the dust collecting box 210 . In addition, the filter box 223 has a communication space formed in an area corresponding to the communication hole 211 , and is preferably formed so as to cover the communication hole 211 . In addition, the filter box 223 has a plurality of first filtration holes (not shown) formed on the outer circumferential surface so that air passes through, and foreign substances in the air remain in the communication space. At this time, the filter box 223 is formed to have an open lower portion, and the bottom surface of the dust collecting box 210 corresponding to the communication space is formed to be open. Here, the communication space of the filter box 223 corresponds to the inlet section 221 of the flow path, and the flow path outside the filter box 223 corresponds to the outlet section 222 .

The auxiliary filter 224 is installed on the inner surface of the filter box 223, and a plurality of second filtering holes (not shown) are formed so that air is passed through, and foreign substances in the air are filtered out. At this time, it is preferable that a plurality of auxiliary filters 224 are installed along the inner surface of the filter box 223 .

The transmission member 230 has a connecting pipe 231 connected to the dust collecting box 210 so that one end communicates with the outlet section 222, and the other end of the connecting pipe 231, the connecting pipe ( A connection box 232 provided with an arrangement space 233 in which the first unit pipe of the cyclone unit is installed is provided so that the air passing through 231 can be introduced into the cyclone unit.

The connecting pipe 231 has one end connected to the rear part of the dust collecting box 210 and is bent downward to extend a predetermined length. In addition, it is preferable that a flow path is formed in the connection pipe 231 so that air can flow therein.

The connection box 232 is formed in a cylindrical shape in which the arrangement space 233 is provided, and the other end of the connection pipe 231 is connected to an outer circumferential surface. At this time, the connection pipe 231 is connected to the connection box 232 so that the extension direction of the other end is spaced apart from the center of the arrangement space 233 so that air flows in a spiral track along the inner wall surface of the connection box 232 . desirable. In addition, the connection box 232 is formed to be curved so that the inner circumferential surface is convex to the outside so that the air introduced therein can be easily guided in an annular shape along the inner circumferential surface.

Here, in the cyclone unit 10 , the first unit pipe 20 is installed in the arrangement space 233 of the connection box 232 , and the center of the first flow space 21 of the first unit pipe 20 is the arrangement space. It is preferably arranged so as to be located coaxially with the center of 233 . In addition, the cyclone unit 10 is installed so that the second unit pipe 30 is exposed outside the right side of the connection box 232 , and the other end of the discharge pipe connected to the first unit pipe 20 is outside the left side of the connection box 232 . installed to be exposed.

The collection bag 240 communicates with the inlet section 221 so as to collect foreign substances filtered by the filter member 220, that is, the bottom surface of the dust collecting box 210, that is, the open dust collecting box 210. is detachably installed on the At this time, although not shown in the drawing, the collection bag 240 is provided with an accommodating space therein, and it is preferable that the upper part is opened.

Meanwhile, the cyclone unit 10 further includes a cyclone dust collecting filter 50 installed at the end of the second unit pipe 30 to collect foreign substances separated from the air. The cyclone dust collecting filter 50 is connected to the end of the second unit pipe 30 , and an accommodation space is provided therein so that foreign substances discharged from the second unit pipe 30 can be accommodated. Here, it is preferable that the cyclone dust collecting filter 50 is detachably coupled to the second unit pipe 30 . On the other hand, the cyclone unit 10 and the connection box 232 are not limited to the illustrated example, but in a standing state such that the first unit tube 20 and the second unit tube 30 are sequentially arranged in the vertical direction. It may be installed in the loading box 130 .

In addition, the road surface cleaning apparatus 100 using a cyclone according to the present invention is installed in the body part 110 at a position adjacent to the suction nozzle 120 to supply foreign substances on the road surface to the suction nozzle 120 side. A brush unit 300 is further provided.

The brush unit 300 includes a support frame 310 supported by the main body 110 adjacent to the suction nozzle 120 by a support member 311 , and rotatably installed on the support frame 310 . The rotation plate 320, the brush member 330 installed on the rotation plate 320 to interfere with foreign substances on the road surface, and the rotation plate 320 so that the foreign substances on the road surface are drawn into the suction nozzle 120 side ), the collision preventing unit 350 and the brush member 330 to prevent the brush member 330 or the rotating plate 320 from colliding with the obstacle on the road surface. A scattering prevention part 360 installed on the support frame 310 to spray a scattering prevention liquid to the road surface is provided to prevent scattering of foreign substances on the road surface.

A plurality of support frames 310 are supported to be spaced apart from the front with respect to the main body 110 by the support members 311 . Here, the support member 311 includes a plurality of first pivoting links 312 rotatably installed on the main body 110 , and a first link driving member (not shown) for rotating the first pivoting links 312 , and , and a plurality of second pivoting links 313 rotatably installed on the first pivoting link 312 , and a second link driving member (not shown) for rotating the second pivoting link 313 .

The first rotation link 312 extends in the front-rear direction, and the rear end is connected to the main body part 110 to be rotatable in the vertical direction. At this time, it is preferable that the first rotational links 312 are installed on the main body 110 at positions spaced apart by a predetermined distance in the left and right directions with respect to the suction nozzle 120 .

One end of the first link driving member is rotatably connected to the first rotatable link 312 , and the other end is rotatably connected to the main body 110 , and actuators whose lengths are stretched at both ends are applied. Meanwhile, the first link driving member is not limited thereto, and any rotation means capable of rotating the first rotation link 312 may be applied.

The second pivoting link 313 extends in the front-rear direction, and the support frame 310 is installed at the front end. The rear end of the second pivoting link 313 is installed rotatably in the left and right directions at the front end of the first pivoting link 312 . Although not shown in the drawing, the second link driving member is a rotation motor installed at the rear end of the second rotation link 313 to rotate the second rotation link 313 in the left and right direction, but is not limited thereto. Any rotation means capable of rotating the second rotation link 313 is applicable.

The support frame 310 is formed in a plate shape having a predetermined thickness, and is installed at the front end of the second pivoting link 313 . The rotation plate 320 is rotatably installed on the lower surface of the support frame 310 and is formed in a disk shape having a predetermined thickness. When a plurality of brush members 330 are provided on the lower surface of the rotation plate 320 , the brush member 330 extends downward with respect to the rotation plate 320 so that the lower end can be in contact with the road surface. In this case, the brush member 330 is preferably formed of a flexible material to be curved when in contact with the road surface.

The rotating part 340 is installed in the support frame 310 , and an electric motor installed at the rotation center of the rotating plate 320 to apply a rotational force to the rotating plate 320 is applied. Meanwhile, the rotation unit 340 is not limited thereto, and any driving means capable of rotating the rotation plate 320 may be applied. Meanwhile, the first and second link driving members and the rotating unit 340 operate according to a control signal input by an operator through a control panel provided on the boarding member 113 .

The anti-collision unit 350 includes a bracket 351 installed on the support frame 310 and a protective roller rotatably installed on the bracket 351 , and an outer circumferential surface protrudes to the outside of the rotation plate 320 . (352) is provided.

A plurality of the brackets 351 are respectively installed on the support frame 310 . That is, the bracket 351 is installed on the left edge of the support frame 310 located on the left side of the main body 110 and on the right edge of the support frame 310 located on the right side of the main body 110 , respectively. The bracket 351 extends a predetermined length in the front-rear direction, and is formed to be curved to have a predetermined curvature.

A plurality of protection rollers 352 are rotatably installed on the bracket 351 , and are formed to have a predetermined radius so that an outer circumferential surface protrudes to the outside of the rotation plate 320 . At this time, the protective roller 352 is preferably formed of a material having a predetermined elasticity in order to prevent the transmission of an impact upon collision with an obstacle. It is possible to prevent the brush unit 300 from being damaged even if it collides with an obstacle on the road surface by the collision preventing unit 350 configured as described above.

The scattering prevention part 360 is installed on the support frames 310, respectively, and a plurality of spray nozzles 361 for spraying the scattering liquid to the road surface, and the main body part 110, the scattering prevention liquid is installed on the spray nozzle 361. A supply unit (not shown) for supplying the

The spray nozzle 361 is installed in front of the support frame 310 to spray the anti-scattering liquid to the road surface below. Although not shown in the drawing, the supply part is installed on the main body 110 and contains a receiving tank in which the scattering prevention liquid is accommodated, a supply pipe having both ends installed in the receiving tank and the injection nozzle 361, respectively, and installed in the supply pipe to the receiving tank A supply pump for pumping the received scattering prevention liquid to the injection nozzle 361 is provided. Although not shown in the drawings, the supply pump is preferably operated according to a control signal input by an operator through a control panel provided on the boarding member 113 .

The scattering prevention part 360 sprays the scattering prevention liquid onto the road surface, so that foreign substances on the road surface are prevented from scattering by the scattering prevention liquid and is easily sucked into the suction nozzle 120 to improve the cleaning efficiency.

The road surface cleaning apparatus 100 having a cyclone unit according to the present invention configured as described above filters foreign substances in the air by flowing the air sucked in from the suction unit 140 along a spiral orbit, so that it has a relatively high cleaning efficiency even after using it for a long time. It has the advantage of being able to provide

Meanwhile, FIGS. 12 to 15 show a road surface cleaning apparatus 400 having a cyclone unit according to another embodiment of the present invention.

Elements having the same function as in the drawings shown above are denoted by the same reference numerals.

Referring to the drawings, the road surface cleaning apparatus 400 having the cyclone unit is installed in the injection nozzle 361 in front of the suction port to interfere with the foreign substances on the road surface to disperse the mutually fixed foreign substances 410. provide more

The interference unit 410 includes an interference frame 411 installed at the front end of the suction nozzle 120, and an interference member 412 rotatably installed in the interference frame 411 to interfere with foreign substances on the road surface; An angle limiting member 413 installed in the interference frame 411 to interfere with the interference member 412 so as to limit a rotation angle at which the interference member 412 is rotated forward to a preset angle; An external force applying member 414 for applying an external force to the interference member 412 is provided so that the interference member 412 is rotated forward.

The interference frame 411 is installed on the suction nozzle 120 at positions spaced apart from each other in the left and right directions based on the plurality of suction ports. At this time, the interference frame 411 is extended forward a predetermined length with respect to the suction nozzle (120). In addition, the interference frame 411 has an insertion hole 415 formed at the front end so that the rotation shaft 418 of the first unit panel 416 of the interference member 412 to be described later can be rotatably inserted. At this time, the insertion hole 415 is penetrated in the left and right direction, it is preferable that a predetermined length is extended in the vertical direction.

The interference member 412 has a first unit panel 416 having one end rotatably installed on the interference frame 411 by a rotation shaft 418 and extending in a direction away from the rotation shaft 418, and the A second second formed at the other end of the first unit panel 416 and extending in a direction crossing the extension direction of the first unit panel 416 so that the end is adjacent to the road surface in order to interfere with foreign substances on the road surface. A unit panel 417 is provided.

The first unit panel 416 is provided with rotation shafts 418 on the left and right sides of the front end, respectively, and the corresponding rotation shaft 418 is inserted into the insertion hole 415 of the interference frame 411 to rotate the interference frame 411. is supported on The first unit panel 416 extends a predetermined length backward from the rotation shaft 418 .

The second unit panel 417 extends to the front end of the first unit panel 416 and extends forward with respect to the first unit panel 416 by a predetermined length. In this case, it is preferable that the second unit panel 417 be inclined downward as the distance from the first unit panel 416 increases so that the front end thereof is adjacent to the road surface. The foreign substances adhered to each other on the road surface interfere with the front end of the second unit panel 417 and are sucked into the suction nozzle 120 in a reduced volume state.

The angle limiting member 413 is installed on the upper interference frame 411 of the second unit panel 417 to limit the forward rotation angle of the second unit panel 417 . Each of the angle limiting members 413 is formed to protrude from the interference frame 411 toward the suction port. The second unit panel 417 is prevented from being rotated forward by the angle limiting member 413 .

The external force applying member 414 is rotatably installed in the interference frame 411 at the rear end of the rear end spaced apart from the rotation shaft 418, and applies an external force to the interference member 412 by its own weight. The front end is formed to extend forward from the center of rotation so as to contact the upper portion of the first unit panel (416). Here, although the external force applying member 414 is not shown in the drawings, a weight having a predetermined weight may be installed at the front end thereof.

In the case of a foreign material having a relatively large volume, the second unit panel 417 is rotated backward by interference with the foreign material according to the movement of the main body 110 . The space between the road surface and the second unit panel 417 is expanded by the second unit panel 417 which is rotated backward, so that the foreign material is easily introduced into the suction nozzle 120 . At this time, when a foreign material having a larger volume than the space between the expanded second unit panel 417 and the road surface is introduced, the rotation shaft 418 of the first unit panel 416 is inserted into the insertion hole 415 as shown in FIG. 15 . As it rises upward, the space between the second unit panel 417 and the road surface is further expanded, so that the foreign material can be easily introduced into the suction nozzle 120 .

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments presented herein but is to be construed in the widest scope consistent with the principles and novel features presented herein.

10: cyclone unit 20: first unit tube
21: first flow space 22: inlet
30: 2nd unit building 31: 2nd flow space
40: flow guide part 41: induction flow path
42: induction port 50: air filtering unit
51: first flange member 52: second flange member
53: filter net 100: road surface cleaning device
110: main body 120: suction nozzle
121: auxiliary panel 130: loading box
140: suction unit 200: foreign matter filter unit
210: dust collector 220: filter member
230: filter member 240: collection bag
300: brush unit

Claims (24)

a first unit pipe having a first flow space formed therein, and having a plurality of inlets formed on an outer circumferential surface so that air forcedly blown from the suction unit can be introduced into the first flow space;
a second unit pipe provided at a lower portion of the first unit pipe and having a second flow space communicating with the first flow space therein, the second flow space having an inner diameter that is reduced toward a lower side;
The air introduced into the first flow space flows in a spiral path along the inner wall of the first unit pipe to separate fine dust from the air. provided with a flow guide unit installed;
cyclone unit.
According to claim 1,
The flow guide part is installed on the outer circumferential surface of the first unit pipe, has an induction passage communicating with the inlet, and extends from the inlet to a predetermined length in the circumferential direction of the first unit pipe, and is provided with external air at the end. A guide port communicating with the guide flow path is formed so that the
cyclone unit.
3. The method of claim 2,
The inlet is formed in the first unit pipe to penetrate in a radial direction of the first unit pipe,
The guide hole is formed in the flow guide portion to penetrate along the circumferential direction of the first unit tube,
cyclone unit.
4. The method of claim 2 or 3,
In order to guide the air flowing into the first flow space downward along the inner wall surface of the first unit pipe, the flow guide part has a bottom surface of one end adjacent to the inlet port below the bottom surface of the other end where the induction port is provided. inclined to be positioned,
cyclone unit.
4. The method of claim 2 or 3,
The flow guide part has an inner surface opposite to the outer circumferential surface of the first unit pipe with respect to the longitudinal centerline of the induction flow path is formed to be curved such that the separation distance from the induction port to the center of the first flow space decreases toward the inlet side. ,
cyclone unit.
3. The method of claim 2,
It further includes a discharge pipe installed at the upper part of the first unit pipe so that air rising from the second unit pipe can be discharged to the outside, the end of which is introduced into the first unit pipe, and is formed to be located below the inlet port. doing,
cyclone unit.
a main body provided with a driving unit to travel on the road surface of the cleaning target area;
a suction nozzle provided in the main body and having a suction port so that foreign substances on the road surface can be introduced;
a loading box installed in the main body and having a loading space therein so that foreign substances introduced through the suction nozzle can be loaded;
a suction unit installed in the suction nozzle to suck the foreign material on the road surface through the suction nozzle and transfer it to the loading space of the loading box;
a foreign substance filter unit installed in the loading box to filter foreign substances in the air sucked by the suction unit; and
A cyclone unit connected to the foreign material filter unit and rotating the air passing through the foreign material filter unit in a spiral orbit to separate fine dust from the air;
A road surface cleaning device using a cyclone unit.
8. The method of claim 7,
The foreign material filter unit
a dust collecting box installed inside the loading box, connected to the suction unit, and provided with a flow path through which the air sucked by the suction unit flows;
Installed on the flow path to filter foreign substances in the air introduced into the flow path, the flow path is formed to divide the flow path into an inlet section through which air is introduced from the suction unit and an outlet section through which air from which foreign substances are filtered is discharged filter member; and
A transmission member communicating with the outlet section of the dust collecting box and supplying the air passing through the filter member to the cyclone unit;
A road sweeper equipped with a cyclone unit.
9. The method of claim 8,
The foreign matter filter unit further includes a collection bag detachably installed in the dust collecting box so as to communicate with the inlet section so as to collect the foreign matter filtered by the filter member.
A road sweeper equipped with a cyclone unit.
9. The method of claim 8,
The cyclone unit is
a first unit pipe having a first flow space formed therein and having a plurality of inlets formed on an outer circumferential surface so that the air supplied by the transmission member can be introduced into the first flow space;
a second unit pipe provided at a lower portion of the first unit pipe and having a second flow space communicating with the first flow space therein, the second flow space having an inner diameter that is reduced toward a lower side;
The air introduced into the first flow space flows in a spiral path along the inner wall of the first unit pipe to separate fine dust from the air. provided with a flow guide unit installed;
A road sweeper equipped with a cyclone unit.
11. The method of claim 10,
The flow guide part is installed on the outer circumferential surface of the first unit pipe, has an induction passage communicating with the inlet, and extends from the inlet to a predetermined length in the circumferential direction of the first unit pipe, and is provided with external air at the end. A guide port communicating with the guide flow path is formed so that the
A road sweeper equipped with a cyclone unit.
12. The method of claim 11,
The inlet is formed in the first unit pipe to penetrate in a radial direction of the first unit pipe,
The guide hole is formed in the flow guide portion to penetrate along the circumferential direction of the first unit tube,
A road sweeper equipped with a cyclone unit.
13. The method of claim 11 or 12,
In order to guide the air flowing into the first flow space downward along the inner wall surface of the first unit pipe, the flow guide part has a bottom surface of one end adjacent to the inlet port below the bottom surface of the other end where the induction port is provided. inclined to be positioned,
A road sweeper equipped with a cyclone unit.
13. The method of claim 11 or 12,
The flow guide portion is formed to be curved to have a predetermined curvature on the side opposite to the outer circumferential surface of the first unit tube with respect to the longitudinal centerline of the guide passage,
A road sweeper equipped with a cyclone unit.
11. The method of claim 10,
The cyclone unit is installed on the upper part of the first unit pipe so that air rising from the second unit pipe can be discharged to the outside, and the end of the cyclone unit is introduced into the first unit pipe, and the discharge pipe is formed to be located below the inlet port. further comprising;
A road sweeper equipped with a cyclone unit.
12. The method of claim 10 or 11,
The transmission member is
a connection pipe having one end connected to the dust collecting box to communicate with the outlet section; and
It is connected to the other end of the connection pipe, the connection box provided with an arrangement space in which the first unit pipe of the cyclone unit is installed so that the air that has passed through the connection pipe can be introduced into the cyclone unit; and
The connection pipe is connected to the connection box so that the extension direction of the other end is spaced apart from the center of the arrangement space,
A road sweeper equipped with a cyclone unit.
11. The method of claim 10,
The cyclone unit further includes a cyclone dust collecting filter detachably installed under the second unit pipe to collect foreign substances separated from the air.
A road sweeper equipped with a cyclone unit.
8. The method of claim 7,
a brush unit installed in the body portion adjacent to the suction nozzle to supply foreign substances on the road surface to the suction nozzle side;
The brush unit
a support frame supported on the body portion adjacent to the suction nozzle by a support member;
a rotation plate rotatably installed on the support frame;
a brush member installed on the rotating plate to interfere with foreign substances on the road surface; and
A rotating part for rotating the rotating plate so that foreign substances on the road surface are drawn into the suction nozzle side;
A road sweeper equipped with a cyclone unit.
19. The method of claim 18,
The brush unit further includes a scattering prevention part installed on the support frame to spray the scattering prevention liquid to the road surface in order to prevent scattering of foreign substances on the road surface by the brush member.
A road sweeper equipped with a cyclone unit.
19. The method of claim 18,
The brush unit further includes a collision preventing unit to prevent the brush member or the rotating plate from collided with the obstacle on the road surface;
The anti-collision unit
a bracket installed on the support frame; and
A protective roller that is rotatably installed on the bracket and has an outer circumferential surface protruding to the outside of the rotating plate;
A road sweeper equipped with a cyclone unit.
8. The method of claim 7,
An interference unit installed in the injection nozzle in front of the suction port to interfere with the foreign substances on the road surface to disperse the mutually adhering foreign substances;
A road sweeper equipped with a cyclone unit.
22. The method of claim 21,
The interference unit
an interference frame installed at the front end of the suction nozzle;
One end is rotatably installed on the interference frame by a rotation axis, a first unit panel extending in a direction away from the rotation axis, and the other end of the first unit panel are formed to interfere with foreign substances on the road surface an interference member provided with a second unit panel extending in a direction crossing the extending direction of the first unit panel so that an end thereof is adjacent to the road surface;
an angle limiting member installed in the interference frame to interfere with the interference member so as to limit a rotation angle at which the interference member is rotated forward to a preset angle; and
and an external force applying member for applying an external force to the interference member so that the interference member is rotated forward.
A road sweeper equipped with a cyclone unit.
23. The method of claim 22,
One end of the external force applying member is rotatably installed in the interference frame at a position spaced rearward with respect to the rotation axis, and the other end is the upper part of the first unit panel so as to apply an external force to the interference member by its own weight. formed extending forward from the center of rotation so as to be in contact with
A road sweeper equipped with a cyclone unit.
24. The method of claim 22 or 23,
The first unit panel is installed in the interference frame to be movable in the vertical direction so that the space between the road surface and the interference member can be expanded.
A road sweeper equipped with a cyclone unit.

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