RU2220642C2 - Cyclone with dust catcher - Google Patents

Abstract

FIELD: vacuum air cleaning equipment. SUBSTANCE: cyclone has case, inlet air duct connected to cyclone case for sucking air and foreign matter, air discharge duct for discharging of air sucked into cyclone case, discharge orifice for discharge of foreign matter separated from air in cyclone case, and laminar flow creating apparatus extending along axial line of discharge air duct and arranged opposite to site where discharge air duct is located. Laminar flow creating apparatus is composed of plurality of blades having closed ends and spaced from one another by predetermined distance. Each blade is inclined at set angle with respect to direction of rotation of foreign matter in cyclone case. Said apparatus may be made from netted cylindrical shell or plurality of flat blades intersecting one another. Cyclone may alternatively comprise air flow guide made in the form of skirt and extending toward air discharge duct, said guide being arranged opposite to site where air discharge duct is located in cyclone case, and blades intersecting one another and adapted for inhibiting of rotating force and creating laminar flow. Blades are provided on inner side of air flow guide. Each of blades for creating of laminar air flow is inclined at set angle with respect to direction of rotation of foreign matter rotating in cyclone case. Length of laminar flow creating apparatus is 0.4-0.6 the distance between inlet side of air discharge duct and laminar flow creating apparatus. EFFECT: increased efficiency by reducing pressure losses through providing of laminar character to air flow at discharge end of air discharge duct and by eliminating penetration of small dust particles into air to be discharged. 11 cl, 14 dwg, 1 tbl

Description

 The group of inventions relates to a cyclone with a dust collector with a reduced intensity of air turbulence created in it.

 The air in the room is usually sucked into the vacuum cleaner using a suction force, and the separation of impurities from the air is carried out to collect them.

 There are various types of cyclones with dust collectors, in particular a cyclone with a dust collector in which air inlet and outlet are in the forward direction, and another cyclone with a dust collector in which air inlet and outlet are reversed (for example, US 5160356 A, 03.11 .1992), or in tangential directions.

 A known cyclone with a dust collector in which air flows in the forward direction (US 5350432 A, 04/27/1994).

 This cyclone comprises a housing 10 (see FIGS. 1-3), an inlet duct 11 for sucking in the air and foreign impurities in the room, an exhaust duct 12 for discharging air, and a collecting hopper 13 for collecting foreign impurities separated from the air.

 The inlet duct 11 extends in a tangential direction into the cyclone body 10. The exhaust duct 12 has one end that extends through the upper end of the cyclone body 10 into it. The collection hopper 13 is located under the cyclone body 10 and is connected with its inner side through the outlet 14 for impurities.

 Thus, if a suction force is generated inside the housing 10, dust containing air enters the housing 10 through the inlet duct 11. In addition, the intake duct 11 extends tangentially from the outer loop of the cyclone housing 10, so that air is applied to the air entering the housing 10 centrifugal force. That is, air and impurities simultaneously entering the cyclone body 10 rotate around the inner wall of the body 10, resulting in a centrifugal force. Therefore, extraneous impurities having a mass are separated from almost no mass air and pass along the inner wall of the housing 10. Then, the extraneous impurities are lowered by their weight and collected in the collection hopper 13, passing through the outlet 14 for extraneous impurities.

As follows from the equation F = m • e • ω ² , where F is the centrifugal force; m is the mass; e is the distance between the center of the cyclone body and its inner wall; ω is the angular velocity, air having a mass almost approaching zero is not subjected to centrifugal force, while extraneous impurities having mass rotate by centrifugal force around the inner wall of the cyclone body 10. Air separated from impurities is discharged through the exhaust duct 12, in the same way as air is discharged, which rises along the central part of the cyclone body 10.

 However, the descending air drawn into the housing 10 interacts with the exhaust air that rises from the bottom of the cyclone housing 10. Therefore, a turbulent zone "A" is formed (figure 2).

 The interaction occurs due to the rotational force of the exhaust air and due to the fact that the cross-sectional area of the rotating flow in the cyclone body 10 is smaller than the cross-sectional area of the exhaust duct 12.

 The turbulent flow increases the noise and causes a pressure drop during the operation of the cyclone with the dust collector, resulting in reduced dust collection efficiency. In other words, dust passing to the lower part of the housing 10 and to the dust collector 13 will enter the exhaust air, which exits through the exhaust duct 12, thereby reducing the total dust collection efficiency.

 In particular, since extraneous impurities that are not discharged rotate in the lower part of the cyclone body 10, where the outlet for extraneous impurities is located, it is most likely that extraneous impurities will enter the discharged air.

 In addition, the released fine dust can fall into various devices designed to create a suction force, in particular into the fan motor, thereby creating a risk of damage to it.

 Therefore, to solve these problems, when a cyclone with a dust collector according to the prior art is used as a vacuum cleaner, a separate filter must additionally be provided inside the vacuum cleaner housing.

 A known cyclone with a dust collector comprising a cyclone body, an inlet duct connected to the cyclone body for sucking in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow provided on an axial line along the outlet duct (JP 60-147267 A, 08/03/1985).

 However, in this cyclone, the passage of fine dust into the air discharged from the cyclone is not completely eliminated.

 The objective of the group of inventions is the creation of a cyclone with a dust collector, providing a technical result, which consists in preventing the passage of fine dust into the laminar air flow released from the cyclone.

 This technical result is achieved in that the cyclone with a dust collector comprises a cyclone body, an inlet duct connected to the cyclone body for sucking in air and foreign impurities, an exhaust duct for discharging air drawn into the cyclone body, an exhaust outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow, formed of many blades with closed ends, spaced a certain distance from each other, provided on howl diverter line along the duct, wherein the means for creating a laminar flow is arranged at a location opposite the place where the cyclone is located within the housing outlet duct.

 Each of the blades of the means for creating a laminar flow is inclined at a certain angle with respect to the direction of rotation of the impurities rotating in the cyclone body.

 Means for creating a laminar flow has a length that is 0.4-0.6 of the distance between the inlet side of the exhaust duct and means for creating a laminar flow.

 Preferably, the length is 0.5 distance between the inlet side of the exhaust duct and the laminar flow means.

 In an embodiment of the invention, the cyclone with a dust collector comprises a cyclone body, an inlet duct connected to the cyclone body for drawing in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow formed from a mesh cylindrical casing provided on an axial line along the outlet duct, while means for creating a laminar otok is located at a location opposite the place where the body of the cyclone is deferent duct.

 Means for creating a laminar flow has a length that is 0.4-0.6 of the distance between the inlet side of the exhaust duct and means for creating a laminar flow.

 Preferably, the length is 0.5 distance between the inlet side of the exhaust duct and the laminar flow means.

 In another embodiment of the invention, the cyclone with a dust collector comprises a cyclone body, an inlet duct connected to the cyclone body for drawing in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an outlet for discharging foreign impurities separated from the air in the cyclone body and means for creating a laminar flow formed from a plurality of flat blades intersecting each other, provided on an axial line along the outlet duct, wherein GUT for creating a laminar flow is arranged at a location opposite the place where the cyclone is located within the housing outlet duct.

 Means for creating a laminar flow has a length that is 0.4-0.6 of the distance between the inlet side of the exhaust duct and means for creating a laminar flow.

 Preferably, the length is 0.5 distance between the inlet side of the exhaust duct and the laminar flow means.

 As an embodiment of the invention, the cyclone with a dust collector comprises a cyclone body, an inlet duct connected to the cyclone body for sucking in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an outlet for discharging foreign impurities separated from the air in the cyclone body, having the shape of the skirt is an air flow guide extended to the exhaust duct and located on the opposite side with respect to the place where the exhaust air is located in the cyclone body a gadfly, and blades located at the intersection to weaken the rotational force and form a laminar flow, provided on the inside of the air flow guide.

 The cyclone may further comprise a support protruding between the air flow guide and the inner wall of the cyclone body to a certain height.

 Figure 1 shows the isometric cyclone known from US 5350432 with a dust collector; figure 2 is a section bB in figure 1; figure 3 is a section bb in figure 2; in FIG. 4 - a cyclone with a dust collector and with a cross-shaped blade device, functioning as a means for creating a laminar flow, according to the invention, a longitudinal section; figure 5 is the same, an embodiment of a cyclone; in FIG. 6-8 - embodiments of the cross-shaped blade device; in FIG. 9 - cylindrical blade device; figure 10 is a section GG in fig. 9; figure 11 and 12 is a variant of the invention with a mesh cylindrical casing; in FIG. 13 is another embodiment of the invention; on Fig - part of the cross-shaped blade device according to Fig in isometric view.

 The cyclone contains a housing 15, a dust collector 16 and a cross-shaped vane device 17, which is a means for creating a laminar flow located on an axial line along the exhaust duct located in the housing 15 and at the place opposite to the place where the exhaust duct 18 is located in the cyclone housing (Fig. 4 and 5).

 The cross-shaped blade device 17 is formed by two flat blades 19 intersecting one another and can have various shapes, for example, a rectangular shape, a triangular shape and an elliptical shape (Fig.6-8).

 In an embodiment of the invention, the cross-shaped blade device 17 may be formed of a plurality of flat blades 19 intersecting each other.

 The cross-shaped vane device 17 has a length of 0.4-0.6 of the distance L between the exhaust duct 18 and the device 17. This is due to the fact that the cross-shaped vane device is located at the place where the air is sucked into the cyclone body 15 through its inlet duct 20 into the exhaust air, so that it is desirable to make the flow of exhaust air laminar and thereby reduce pressure loss.

 If the length of the crosswise vane device 17 is 0.4 times the distance L between the exhaust duct 18 and the device 17 or less, it is difficult to reduce the pressure loss. If the length of the cross-shaped blade device 17 is 0.6, the distance L between the exhaust duct 18 and the device 17 or more, then there is a difficulty associated with the air entering the exhaust air. Therefore, the length of the cross-shaped blade device 17 should be set within 0.4 to 0.6 of the distance L. Preferably, the length of the cross-shaped blade device 17 is 0.5 of the distance L.

 The table shows comparative experimental results reflecting the pressure loss in the cyclone known in the prior art and in the cyclone according to the invention having a cross-shaped blade device 17.

In this table, 0.25 • L, 0.5 • L and 0.75 • L mean that the length of the cross-shaped blade device is 0.25, 0.5 and 0.75 of the distance L between the exhaust duct 18 and the cross-shaped blade device 17 . Moreover, in each experiment, the direction of air flow was the same at a flow rate of about 1.2 m ³ / min.

 As shown in the table, a cyclone with a dust collector according to the invention equipped with a cross-shaped vane device 17 had a slight pressure loss. In particular, the pressure loss was small when the length of the cross-shaped blade device was 0.5 distance L between the exhaust duct 18 and the cross-shaped blade device 17.

 In the embodiment of the invention according to FIGS. 9-10, the means for creating a laminar flow is a cylindrical blade device 21 having a plurality of blades 22 having closed ends and spaced a certain distance from each other. The first supporting element 23 of the cylindrical blade device 21 is provided on one side of the cylindrical blade device 21, and the second supporting element 24 of the blade device having a through hole in the center is provided on its other side. The first support element 23 and the second support element 24 of the blade device are facing one another. The blades 22 are inclined at a certain angle along the entire circumference of each inner side of the support elements 23 and 24 of the blade device. In addition, all the blades 22 forming a cylindrical blade device 21 are inclined at a certain angle with respect to the direction of rotation of the impurity rotating in the cyclone body. This design was chosen because in it the flow of exhaust air can be created laminar and at the same time it is possible to prevent the release of fine dust that can enter the exhaust air.

 In other words, the flow of exhaust air, which rises from the bottom of the cyclone body and is passed into the exhaust duct, retains a certain rotational force. Since the fine dust partially got into the exhaust air, the exhaust air hits the cylindrical blade device 21.

 In addition, the respective blades 22 forming a cylindrical blade device 21 are inclined at a certain angle with respect to the direction of rotation of the exhaust air stream. Therefore, the dust that has fallen into the discharged air strikes against the respective blades 22, as a result of which the fine dust bounces to the inner wall of the cyclone body.

 In contrast, air passes into the interior of the cylindrical blade device 21 through the cavities between the respective blades 22 when rotated around the circumference. Then, air is discharged through a discharge duct connected to the interior of the cylindrical blade device.

 In addition, the flow of exhaust air loses its rotational force when air passes into the interior of the cylindrical blade device 21. Therefore, the flow of exhaust air can become laminar, resulting in reduced pressure loss and noise.

 The means for creating a laminar flow according to the invention is not limited by the configurations in the described embodiments of the invention and can be made in the form of a mesh cylindrical casing 25 (Fig. 11) or a perforated pipe 26 (Fig. 12) having a plurality of through holes 27 along the circumference.

 In the embodiment of the invention according to FIGS. 13 and 14, in the cyclone body 15 on the side opposite to the place where the exhaust duct 18 is located in the body 15, an air flow guide 28 and intersecting vanes 29 of the cross-shaped vane device 30 for weakening the rotational force and laminar formation are located flow. The airflow guide 28 is in the form of a skirt and is elongated towards the exhaust duct 18. The cross-shaped blade device 30 is located inside the airflow guide 28. A support 31 extends between the airflow guide 28 and the inner wall of the cyclone body 15, so that a certain gap is formed between the air flow guide 28 and the inner wall of the cyclone body 15. In this design, the discharged air is generated by the air flow guide 28 and the fine dust in the impurities is rotated in the cyclone body 15 without interference for it to exit the discharged air.

 In other words, the air flow guide 28 is formed so that it is extended toward the exhaust duct 18, and the dust rotation point is allocated a certain distance H from the place where the exhaust air is formed by the air flow guide 28. Therefore, the flow of exhaust air can be formed properly and the inclusion of foreign impurities in the exhaust air can be prevented.

 In addition, although fine dust enters the discharged air in a small amount, it is repelled by a cross-shaped blade device 29 provided on the inside of the air flow guide 28.

 To reduce pressure loss, the cross-shaped blade device 29 creates a dust-free laminar flow of exhaust air.

 The cyclone with a dust collector according to the described group of inventions has the following advantages.

 Since a means for creating a laminar flow is provided in the cyclone body, the turbulence of the discharged air is eliminated, as a result of which the air is discharged in accordance with the task. This reduces pressure loss and noise due to pressure loss.

 In addition, preventing the ingress of fine dust into the exhaust air increases the efficiency of dust collection, as a result of which only clean air is released and there is no need for a separate filter in the vacuum cleaner.

 Since an air flow guide is additionally formed in the cyclone body, the inclusion of impurities in the exhaust air can be prevented.

 For specialists in the field of technology to which the group of inventions relates, it is obvious that in a cyclone with a dust collector according to these inventions, various modifications and changes can be made without departing from the essence or scope of the inventions.

Claims (12)

1. A cyclone with a dust collector comprising a cyclone body, an inlet duct connected to the cyclone body for sucking in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an exhaust outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow formed from a plurality of blades with closed ends spaced a certain distance from each other, provided on an axial line along the outlet duct, this means for creating a laminar flow is located at a place opposite to the place where the exhaust duct is located in the cyclone body. 2. The cyclone according to claim 1, in which each of the blades of the means for creating a laminar flow is inclined at a certain angle with respect to the direction of rotation of the impurities rotating in the cyclone body. 3. The cyclone according to claim 1, in which the means for creating a laminar flow has a length that is 0.4 ÷ 0.6 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 4. The cyclone according to claim 3, in which the means for creating a laminar flow has a length that is 0.5 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 5. A cyclone with a dust collector, comprising a cyclone body, an inlet duct connected to the cyclone body for drawing in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an exhaust outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow formed from a mesh cylindrical casing provided on an axial line along the exhaust duct, while the means for creating a laminar flow is located in a place opposite the place where the exhaust duct is located in the cyclone body. 6. The cyclone according to claim 5, in which the means for creating a laminar flow has a length that is 0.4 ÷ 0.6 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 7. The cyclone according to claim 6, in which the means for creating a laminar flow has a length that is 0.5 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 8. A cyclone with a dust collector, comprising a cyclone body, an inlet duct connected to the cyclone body for drawing in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an exhaust outlet for discharging foreign impurities separated from the air in the cyclone body, and means for creating a laminar flow, formed from many flat blades intersecting each other, provided on an axial line along the outlet duct, while the means for creating a laminar of the flow is located in the opposite direction to the place where the exhaust duct is located in the cyclone body. 9. The cyclone of claim 8, in which the means for creating a laminar flow has a length that is 0.4 ÷ 0.6 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 10. The cyclone according to claim 9, in which the means for creating a laminar flow has a length that is 0.5 from the distance between the inlet side of the exhaust duct and means for creating a laminar flow. 11. A cyclone with a dust collector, comprising a cyclone body, an inlet duct connected to the cyclone body for sucking in air and impurities, an exhaust duct for discharging air drawn into the cyclone body, an outlet for discharging foreign matter separated from the air in the cyclone body, having the form skirts directing the air flow extended to the exhaust duct and located on the opposite side relative to the place where the exhaust duct is located in the cyclone body, and located e with the intersection of the blades to weaken the rotational force and the formation of a laminar flow provided on the inner side of the air flow guide. 12. The cyclone according to claim 1, which further comprises a support protruding between the air flow guide and the inner wall of the cyclone body to a certain height.

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