KR100386251B1 - Ejector for vacuum cleaner - Google Patents

Abstract

The present invention relates to an ejector of a vacuum cleaner, comprising a casing having a suction space formed therein and communicating with the outside, a suction pump accommodated in the casing to generate suction force, and a suction pump. A filter member disposed on a suction side to block foreign substances sucked with the fluid, and an exhaust reflux connected to a discharge side of the suction pump to return at least a portion of the exhaust discharged from the suction pump to the suction side of the suction pump A vacuum cleaner having a furnace, comprising: an ejector chamber portion having a cylindrical shape and having an outlet side connected to the suction side of the suction pump so that a predetermined low pressure space is formed around the ejector nozzle portion; Ejector nozzle part which is formed to gradually reduce the flow cross-sectional area, the suction side is connected to the exhaust reflux path and the outlet end region is disposed inside the ejector chamber part to inject the fluid flowing along the exhaust reflux path at high speed Wow; Foreign matter is formed on the outer surface of the ejector nozzle part with at least one injection hole formed in the ejector nozzle part disposed in the ejector chamber so that the fluid inside the ejector nozzle part can be injected toward the inside of the ejector chamber part. It characterized in that it comprises a foreign material residue suppression means for suppressing the remaining. Thereby, the ejector of the vacuum cleaner which can suppress that a foreign material remains in the inside of an ejector chamber is provided.

Description

Ejector of vacuum cleaner {EJECTOR FOR VACUUM CLEANER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ejector of a vacuum cleaner, and more particularly, to an ejector of a vacuum cleaner in which foreign matters can be suppressed from remaining in the ejector chamber.

In general, the vacuum cleaner is coupled to the casing is formed in the inlet and outlet, the suction pump accommodated to generate a suction force in the casing, and the lower portion of the casing in communication with each other to suck the foreign matter of the bottom surface with the fluid It has a suction head.

Some of these vacuum cleaners have a vacuum cleaner in which an exhaust reflux path is formed so that a part (or all) of the exhaust discharged from the suction pump can be returned to the suction side so that an air cleaning function is added.

Meanwhile, an ejector nozzle and an ejector having an ejector chamber are formed to form a relatively low pressure region around the ejector nozzle so that the fluid can be injected at a relatively high speed in the exhaust reflux path of the vacuum cleaner. The flow path system of the vacuum cleaner, which has been in communication, has been previously filed in the name of the applicant.

1 is a perspective view of an ejector of a conventional vacuum cleaner, and FIG. 2 is a plan sectional view taken along line II-II of FIG. 1. As shown in these figures, the ejector of the vacuum cleaner is formed in the distal region of the exhaust reflux tube 111 for refluxing part of the fluid discharged from the suction pump of the vacuum cleaner (not shown) to form the exhaust reflux tube 111. The ejector nozzle part 121 which sprays the fluid which flows at high speed, and the ejector chamber part 131 which are arrange | positioned around the ejector nozzle part 121 and form a low pressure area inside are comprised, are comprised.

The ejector chamber 131 has a cylindrical shape, and the expansion pipe 133 is formed at the outlet side end to gradually increase the flow cross-sectional area. An ejector chamber suction pipe 135 is coupled to the other end of the ejector chamber 131 so that fluid can be sucked into the ejector chamber 131.

The ejector nozzle part 121 enters horizontally in the longitudinal direction of the ejector chamber part 131 and extends to the center area of the ejector chamber part 131 by a predetermined horizontal section 122a along the horizontal direction, and a horizontal section ( It has a vertical section 122b that is bent toward the outflow side end portion of the ejector chamber portion 131 from 122a), and the appearance is almost "L" shaped.

By this configuration, when the fluid discharged from the suction pump of the vacuum cleaner flows along the exhaust reflux pipe 111 and is injected toward the inside of the expansion pipe 133 at low pressure and high speed through the ejector nozzle part 121, the ejector chamber The internal space of the portion 131 is relatively low in pressure. Accordingly, the inside of the ejector chamber 131 is made of suction of fluid and foreign matter from the outside through the ejector chamber suction pipe 135.

Fluid and foreign matter sucked into the ejector chamber 131 through the ejector chamber suction pipe 135 flow to the outlet side end area along the longitudinal direction of the ejector chamber 131 and flow into the expansion tube 133. After being discharged from the expansion pipe 133 with the fluid injected at a high speed through the ejector nozzle 121.

However, in the ejector of the conventional vacuum cleaner, the horizontal section 122a of the ejector nozzle portion 121 coupled to the end of the exhaust reflux tube 111 has a diameter smaller than that of the ejector chamber portion 131. It has a horizontally disposed in the flow direction of the fluid and foreign matter introduced from the outside through the ejector chamber suction pipe 135, the ejector nozzle portion (about the flow direction of the fluid sucked through the ejector chamber suction pipe 135) Foreign matter remains in the downstream outer periphery of 121, that is, the upper region of the horizontal section 122a shown in FIGS. 1 and 2. The remaining foreign matters are leaked back to the floor surface through the ejector chamber 37 and the ejector chamber suction pipe 135 at the end of cleaning to contaminate the room.

Accordingly, it is an object of the present invention to provide an ejector of a vacuum cleaner that can suppress the foreign matter remaining inside the ejector chamber.

1 is a perspective view of an ejector of a conventional vacuum cleaner,

FIG. 2 is a plan sectional view taken along line II-II of FIG. 1;

3 is a view showing a state of use of the ejector of the vacuum cleaner according to an embodiment of the present invention,

4 is an enlarged view illustrating main parts of FIG. 3;

5 is a plan sectional view taken along the line VV of FIG. 4;

6 is a cross-sectional view of the ejector of the vacuum cleaner according to another embodiment of the present invention;

7 is a longitudinal sectional view of the ejector of the vacuum cleaner according to another embodiment of the present invention;

8 is an enlarged cross-sectional view taken along the line VII-VII of FIG. 7.

Explanation of symbols on the main parts of the drawings

11: main body casing 13: suction pump

15: filter casing 17: filter member

21: suction head 23: first suction port

24: second suction port 31: suction pipe

33: exhaust reflux pipe 41: ejector chamber

43: ejector nozzle 45: injection hole

The object is, according to the present invention, forming a receiving space therein and the suction passage is formed in communication with the outside, and the suction force so as to be accommodated inside the casing to suck the external fluid through the suction passage A suction pump for generating a gas, a filter member disposed on the suction side of the suction pump to block foreign substances sucked with the fluid, and at least a part of the exhaust discharged from the suction pump by being connected to the discharge side of the suction pump; A vacuum cleaner having an exhaust reflux path for returning the suction pump to a suction side of the suction pump, the vacuum cleaner having a cylindrical shape and having an outlet side interconnected with the suction side of the suction pump to form a predetermined low pressure space around the ejector nozzle part. An ejector chamber portion; Ejector nozzle part which is formed to gradually reduce the flow cross-sectional area, the suction side is connected to the exhaust reflux path and the outlet end region is disposed inside the ejector chamber part to inject the fluid flowing along the exhaust reflux path at high speed Wow; Foreign matter is formed on the outer surface of the ejector nozzle part with at least one injection hole formed in the ejector nozzle part disposed in the ejector chamber so that the fluid inside the ejector nozzle part can be injected toward the inside of the ejector chamber part. It is achieved by the ejector of the vacuum cleaner, characterized in that it comprises a foreign material residue suppression means for suppressing the remaining.

Here, the ejector nozzle portion is introduced so as to penetrate horizontally in the longitudinal direction of the ejector chamber portion, the nozzle end is arranged to be bent toward the outflow end portion of the ejector chamber portion, the injection hole is the ejector along the longitudinal direction of the ejector chamber portion It is preferable that the fluid is injected to the outflow side of the chamber portion.

In addition, the ejector nozzle portion is introduced so as to penetrate horizontally in the longitudinal direction of the ejector chamber portion, and the nozzle end is arranged to be bent toward the outflow end of the ejector chamber portion, and the injection hole is a horizontal fluid in the longitudinal direction of the ejector chamber portion It is effective to be formed so as to be sprayed.

In addition, the ejector nozzle portion is introduced so as to penetrate horizontally in the longitudinal direction of the ejector chamber portion, the nozzle end is arranged to be bent toward the outflow end portion of the ejector chamber portion, the foreign material residue suppression means, in the longitudinal direction of the ejector chamber portion A protrusion projecting from the outer surface of the ejector nozzle portion arranged horizontally toward the outflow side of the ejector chamber portion, a guide portion extending horizontally from the end region of the protrusion portion in the projection direction, and guiding fluid, and a circumferential direction of the projection portion It is preferable to include a plurality of injection holes disposed to be spaced apart from each other along.

Here, it is effective that the flow path of the fluid is formed in the shaft center of the protrusion so that the fluid can be injected.

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

3 is a view showing a state of use of the ejector of the vacuum cleaner according to an embodiment of the present invention, Figure 4 is an enlarged view of the main part of Figure 3, Figure 5 is a cross-sectional view taken along the line V-V of FIG. . As shown in these figures, the vacuum cleaner includes a casing having a main body casing 11 forming a receiving space therein and a suction head 21 integrally coupled to the lower side of the main body casing 11, and a main body casing ( 11) the suction pump 13 accommodated in the interior to generate a suction force, the filter casing 15 that is detachably coupled to one side of the main body casing 11 and collects foreign matter therein, and the filter casing 15 It is configured to include a filter member 17 accommodated therein to block foreign matter from being sucked into the suction pump 13.

The first suction port 23 and the second suction port 24 are formed to be spaced apart from each other by a predetermined distance in the bottom region of the suction head 21, and one end of the main casing 11 is disposed in the filter casing 15. The first suction pipe 31 is installed so as to be in communication with the other end and the other end is in communication with the first suction port (23).

Meanwhile, an exhaust port 14 is formed at one side of the suction pump 13 to discharge the fluid, and an exhaust reflux pipe 33 is formed at one side of the exhaust port 14 to form an exhaust reflux path to return the fluid. Is combined. In the distal region of the exhaust reflux tube 33, an ejector 40 of a vacuum cleaner according to an embodiment of the present invention is provided.

The ejector 40 of the vacuum cleaner according to the present invention is disposed in the distal region of the exhaust reflux tube 33 and ejected from the ejector nozzle part 43 and the ejector nozzle part 43 to inject the fluid at a relatively high speed. It is formed through the cylindrical ejector chamber portion 41 disposed in the circumferential region of the ejector nozzle portion 43 and the ejector nozzle portion 43 disposed inside the ejector chamber portion 41 along the ejecting direction of the fluid. It is configured to include the foreign matter residue suppression means implemented by the injection hole 45 is formed so that the fluid in the ejector nozzle portion 43 is injected into the ejector chamber portion 41.

The ejector chamber part 41 is disposed in the main body casing 11 so that the outlet side end faces upward in the up and down direction, and the flow end area of the ejector chamber part 41 is gradually increased so as to gradually increase. The tube 42 is formed. An ejector chamber suction pipe 46 having one end connected to the second suction port 24 is coupled to an opposite end of the ejector chamber portion 41 so that fluid may flow therein.

The ejector nozzle portion 43 penetrates horizontally from the end of the exhaust reflux pipe 33 in the longitudinal direction of the ejector chamber portion 41 and extends to the central region of the ejector chamber portion 41 in the horizontal direction. ) And a vertical section 44b bent upward from the end region of the horizontal section 44a toward the outflow side end region of the ejector chamber portion 41.

The horizontal section 44a of the ejector nozzle section 43 is caused by the fluid inside the ejector nozzle section 43 to be injected into the ejector chamber section 41 on the upper surface of the horizontal section 44a of the ejector nozzle section 43. Injection hole 45 is formed to suppress the foreign matter remaining on the upper surface of the).

By this configuration, when power is applied to the suction pump 13, the suction of the fluid is started from the outside through the first suction port 23, and the fluid and the foreign substance sucked through the first suction port 23 are suction pipes 31. Through the filter casing 15 is introduced into the inside. Foreign matter introduced into the filter casing 15 is blocked by the filter member 17 and collected inside the filter casing 15, and the fluid passing through the filter member 17 passes through the suction pump 13. Some are discharged to the outside through the exhaust port 14.

Some of the fluid discharged from the suction pump 13 flows along the exhaust reflux pipe 33 and is injected into the expansion pipe 42 at low pressure and high speed through the ejector nozzle part 43. As a result, the pressure inside the ejector chamber part 41 becomes relatively low, and the fluid and the foreign matter are sucked from the outside through the ejector chamber suction pipe 46 inside the ejector chamber part 41.

The fluid sucked into the ejector chamber part 41 and the foreign matter flows upward and flows into the expansion pipe 42 to be sucked through the suction pipe 31 together with the fluid injected from the ejector nozzle part 43 and Joined with the foreign matter is sucked into the filter casing (15).

On the other hand, a part of the fluid flowing along the exhaust reflux pipe 33 is injected through the injection hole 45 formed in the horizontal section 44a of the ejector nozzle portion 43, whereby the horizontal section of the ejector nozzle portion 43 This prevents foreign matter from remaining on the upper surface of 44a.

6 is a cross-sectional view of the ejector of the vacuum cleaner according to another embodiment of the present invention. The same reference numerals are given to the same and equivalent parts as the above-described and illustrated embodiments, and detailed description thereof will be omitted. As shown, the ejector 50 of the vacuum cleaner of the present embodiment is disposed around the ejector nozzle part 53 and the ejector nozzle part 53 which are bent in the distal region of the exhaust reflux tube 33, and the inside thereof. As shown in FIG. 6, the ejector chamber part 51 for forming a low pressure region in the upper part and the foreign matter residue suppressing means for suppressing foreign matter remaining inside the ejector chamber part 51 may be provided. It is configured to include.

The ejector nozzle part 53 has a horizontal section 54a arranged horizontally in the longitudinal direction of the ejector chamber part 51 and a vertical section 54b arranged along the longitudinal direction of the ejector chamber part 51. L ”shape. An injection hole 55 is formed in the lower region of the vertical section 54b of the ejector nozzle 53 so that the fluid inside may be injected in parallel with the upper surface of the horizontal section 54a.

By this configuration, almost all of the fluid flowing along the exhaust reflux pipe 33 is injected into the expansion pipe 42 through the nozzle hole 56 at low pressure and high speed, and a part of the oil is injected into the injection hole 55. By spraying to the upper side of the horizontal section 54a through) it is suppressed that the foreign matter remains on the upper surface of the horizontal section (54a).

7 is a longitudinal cross-sectional view of the ejector of the vacuum cleaner according to another embodiment of the present invention, Figure 8 is an enlarged cross-sectional view taken along the line VII-VII of FIG. The same reference numerals are given to the same and equivalent parts as the above-described and illustrated embodiments, and detailed description thereof will be omitted. As shown in these figures, the ejector 60 of the vacuum cleaner of this embodiment is formed around the ejector nozzle portion 63 and the ejector nozzle portion 63 which are bent in the distal region of the exhaust reflux tube 33. The ejector chamber part 61 arrange | positioned so that the low pressure area | region may be formed inside, and the foreign material residue suppression part 67 which suppresses the foreign material remaining inside the ejector chamber part 61 is comprised.

The foreign matter residue suppressing portion 67 is a projection 68 projecting on the upper surface of the horizontal section 54a of the ejector nozzle section 63 and parallel to the horizontal section 64a in the distal region of the projection 68. It is configured to include a guide portion (69) for extending a predetermined guide the fluid. Protruding portion 68 is formed of a tubular body formed with a flow path so that fluid flows to the shaft center, the plurality of injection holes (65a) are spaced apart from each other along the circumferential direction so that the inside and outside communicate with the periphery of the protrusion 68 have. The guide portion 69 is formed with injection holes 65b so that fluid can be injected onto the surface of the guide portion 69.

By this configuration, almost all of the fluid flowing along the exhaust reflux pipe 33 is injected into the expansion pipe 42 through the nozzle hole 66 at low pressure and high speed, and a part of the fluid formed in the protrusion 68 is formed. By spraying through the hole 65a, foreign matters are prevented from remaining on the upper surface of the horizontal section 64a of the ejector nozzle part 63. At this time, a part of the fluid flowing along the axis of the protrusion 68 is injected through the injection hole (65b) formed in the guide portion 69 to suppress the foreign matter remaining on the surface of the guide portion 69. .

As described above, according to the present invention, the ejector nozzle portion is formed so that the fluid is injected at a low pressure high speed to the distal region of the exhaust reflux pipe for refluxing the fluid discharged from the suction pump, so that the low pressure region is formed around the ejector nozzle portion The ejector chamber of the vacuum cleaner which can suppress the foreign matter remaining in the ejector chamber part by providing the ejector chamber part and the foreign material residual suppression means formed so that the fluid inside the ejector nozzle part may be injected into the ejector chamber part, Is provided.

Claims (5)

A casing in which a suction flow path is formed to communicate with the outside, the suction pump is formed inside the casing, and a suction pump generates suction force to suck external fluid through the suction flow path; A filter member disposed on the suction side of the pump to block foreign substances sucked with the fluid, and connected to the discharge side of the suction pump to return at least a portion of the exhaust discharged from the suction pump to the suction side of the suction pump; A vacuum cleaner having an exhaust reflux path, comprising: an ejector chamber portion having a cylindrical shape and having an outlet side interconnected with a suction side of the suction pump so that a predetermined low pressure space is formed around the ejector nozzle portion; Ejector nozzle part which is formed to gradually reduce the flow cross-sectional area, the suction side is connected to the exhaust reflux path and the outlet end region is disposed inside the ejector chamber part to inject the fluid flowing along the exhaust reflux path at high speed Wow; Foreign matter is formed on the outer surface of the ejector nozzle part with at least one injection hole formed in the ejector nozzle part disposed inside the ejector chamber so that the fluid inside the ejector nozzle part can be injected toward the inside of the ejector chamber part. Ejector of the vacuum cleaner comprising a foreign material residue suppression means for suppressing the remaining. The method of claim 1, The ejector nozzle part is introduced so as to penetrate horizontally in the longitudinal direction of the ejector chamber part, and the nozzle end is arranged to be bent toward the outflow end of the ejector chamber part, and the injection hole is disposed in the ejector chamber part along the longitudinal direction of the ejector chamber part. Ejector of the vacuum cleaner, characterized in that the fluid is injected to the outlet side. The method of claim 1, The ejector nozzle portion is introduced so as to penetrate horizontally in the longitudinal direction of the ejector chamber portion, and the nozzle end is arranged to be bent toward the outflow end portion of the ejector chamber portion, and the injection hole is a fluid injection in the longitudinal direction of the ejector chamber portion Ejector of the vacuum cleaner, characterized in that formed so as to. The method of claim 1, The ejector nozzle part is introduced to penetrate horizontally in the longitudinal direction of the ejector chamber part, and the nozzle end is arranged to be bent toward the outflow end of the ejector chamber part, and the foreign material residue suppressing means is horizontally in the longitudinal direction of the ejector chamber part. A protrusion projecting from the outer surface of the ejector nozzle portion to the outflow side of the ejector chamber portion, a guide portion extending horizontally from the end region of the projecting portion in the projecting direction to guide the fluid, and along the circumferential direction of the projecting portion; Ejector of the vacuum cleaner comprising a plurality of injection holes arranged to be spaced apart from each other. The method of claim 4, wherein The ejector of the vacuum cleaner, characterized in that the flow path of the fluid is formed in the axis of the projection so that the fluid can be injected.