KR200182894Y1 - No-duct blower - Google Patents

Abstract

The present invention relates to a ductless blower, and more particularly, to an improvement of a ductless blower having a directional blower head, and to a ductless blower having a structure capable of reducing air blowout noise and blowout resistance. It is about.

The ductless blower according to the present invention generally includes a casing 22 having a hollow cylindrical shape having both ends thereof open at one end thereof with a partial spherical surface 30; An ejection nozzle part 24 having one end forming a partial spherical surface 31 and the other end opened so as to be in contact with the partial spherical surface formed at one end of the casing; And in the ductless blower having a blower fan (26) mounted coaxially with the casing in the casing to blow the wind toward the blowout nozzle, having a diameter approximately equal to the inner diameter of the casing One end 32 is fixed to the inner circumferential surface of the casing, and the other end 34 is provided with a tube 36 of elastic material fixed to the casing inner end of the ejection nozzle part. A guide blade 38 having a predetermined height is installed on the inner circumferential surface of the part at axially equal intervals. The ductless blower according to the present invention has an effect of preventing excessive blowout static pressure, taking out noise and vibration, even if the opening direction of the blowout nozzle portion is changed, and increasing the blowout length.

Description

Ductless blower

The present invention relates to a ductless blower, and more particularly, to an improvement of a ductless blower having a directional blowout nozzle, which can reduce air blowout noise and blowout resistance and compensate for blowout length. It relates to a ductless blower having a.

Unpleasant odor or polluted air inside the room is quickly discharged to the outside, and fresh air from the outside is required for a pleasant residential environment. Especially in closed spaces such as underground parking lots where many vehicles pass by, the pollution of the air is not only severe due to the harmful exhaust gas of the vehicle, but also the indoor space is large so that it is not easy to induce the flow of air. There must be sufficient ventilation performance.

Due to the necessity of coordination of such enclosed spaces, Article 6 of the Enforcement Regulations of the Parking Lot Act requires that the height of parts used for parking in off-street parking lots should be at least 2.1 meters from the floor of the parking lot. It is prescribed that the average of 8 hours should be kept below 50ppm before and after the most frequently used vehicle.

As a typical example of a ventilation system of a conventional underground parking lot, as shown in FIG. 1, an air supply fan 2 for introducing outside air into the underground parking lot from the outside; An air supply duct 4 connected to the air supply fan for sending air introduced by the air supply fan; An exhaust fan 6 for discharging indoor contaminated air to the outside; In addition, there is a so-called 'exhaust and exhaust duct method' provided with an exhaust duct 8 connected to the exhaust fan. In this air supply and exhaust duct system, the air supply duct 4 and the exhaust duct 8 are separated from each other, and each air outlet 10 and the inlet 12 are sequentially installed along the longitudinal direction of the air supply duct and the exhaust duct, respectively. The farther distance is provided from the air supply fan 2 and the exhaust fan 6, the lower the air ejecting ability and the air intake ability. Therefore, even though the duct pipe diameter and the outlet nozzle diameter are designed to equalize the air transfer performance of the air supply duct and the exhaust duct optimally, it is extremely difficult to equally control the air ejection capacity and the air intake ability at each outlet and intake port. In addition, as the ceiling duct (air supply and exhaust duct) has to be installed, the ceiling height is lowered. Therefore, the ceiling height must be increased to comply with the standards prescribed by the Parking Lot Act. This is a factor in increasing construction costs.

In addition, as another example of the conventional ventilation system of the underground parking lot, as shown in Figure 2, the air supply fan (2) for introducing the outside air into the room; A plurality of turbo fans 14 which attract indoor air and blow out at a high speed in a predetermined direction; A plurality of high speed ducts 16 installed in communication with each turbo fan, respectively; A plurality of high speed nozzles 18 branched from each of the high speed ducts for smooth air transfer; In addition, there is a so-called 'high speed nozzle method' provided with the exhaust fan 6. In this high-speed nozzle system, since a predetermined number of turbo fans 14 are installed in the room in order to blow out the indoor air at a high speed, the shortcomings of the air supply / exhaust duct system can be solved to some extent, but the terminal high speed nozzle 18 The problem of low air blowout capacity at) and the ceiling height due to the duct space still remain, and because the blowing capacity of the turbo fan must be large, there is a problem in that a lot of equipment cost, operation cost, and noise are generated.

On the other hand, as recently developed and started to use, as shown in Figure 3, the air supply fan 2 for introducing the outside air from the outside to the room; An exhaust fan 6 which blows out indoor air to the outside; In addition, a plurality of ductless blowing fans 20 for attracting local air in a predetermined area of the indoor area and extracting them in a predetermined direction to smoothly transport air in a predetermined direction throughout the room are provided. Duct blowing method.

As an example of a ductless blower, as shown in FIG. 4, the hollow cylindrical casing 22 which opened at both ends generally; An ejecting nozzle part 24 extending at one end of the casing; And it is common to provide the blowing fan 26 mounted coaxially in the inside of a casing so that a wind may blow to the said ejection nozzle part. However, since the casing 22 and the ejection nozzle part 24 of the ductless blowing fan are fixed integrally in a straight line direction in which the ejection nozzle part has an opening direction coinciding with the axial direction of the casing, in order to control the ejection direction of air, The installation angle (fixed angle to the ceiling, etc.) of the ductless blower 20 itself has to be changed, which is problematic in that the adaptability of the mounting is poor in relation to the plane shape of a building, a pillar, or other facilities. In connection with this problem, as shown in Fig. 5, the distal end portion of the casing is formed into a partially spherical shape, while the engaging portion of the casing of the ejection nozzle portion is located within the spherical distal end portion of the casing. An example of a ductless blower that is formed into a substantially partial sphere that can flow in contact is known. In this example, the blowout nozzle part 24 is a separate body separated from the casing 22, and the blowout nozzle part can flow in any direction within a predetermined angle in a state where the blowout nozzle part is engaged with the casing tip. There is an advantage that the blowing direction can be easily adjusted by rotating only the ejection nozzle portion as needed without changing the mounting angle to the ceiling.

On the other hand, in the structure in which the air blowing nozzle portion can flow at any angle within the casing tip as described above, there is an advantage in that the blowing direction is easily changed, whereas when the blowing nozzle portion is bent, the air is blown out compared to the linear blowing. Particularly, for example, as shown in FIG. 6, a part of the casing inner end (upper side in FIG. 6) of the ejection nozzle part is folded into the casing inner circumferential surface when the ejection nozzle part is bent so that its opening is upward, as shown in FIG. 6. Since a space 28 is formed between them while forming a sharp acute angle α, a part of the air blown out of the blower fan 26 is trapped in the blocked space and causes a very large blowout static pressure and vortex. This not only reduces the blowout performance of the blowing fan, but also causes a large blowout noise and vibration.

The invention devises a ductless blower, in particular, as described above, the front end of the casing in a substantially partial spherical shape, while the engaging portion to the casing of the ejection nozzle part is in contact with the spherical inside of the partial spherical front end of the casing. In the ductless blower having a substantially partial spherical shape so as to flow, even if the opening direction of the ejection nozzle part is changed, an excessive ejection pressure is not generated by eliminating the acute angle of the inner circumferential surface of the casing at the inner end of the ejection nozzle part. Accordingly, it is an object of the present invention to provide a ductless blower capable of properly exhibiting the designed blower capacity and reducing vibration and noise.

Another object of the present invention is to provide a ductless blower that can compensate for the reduction of the air blow-out length in accordance with the angle change of the blowout nozzle.

Hereinafter, the configuration of a ductless blower according to the present invention will be described in detail with reference to the accompanying drawings showing a preferred embodiment thereof.

1 is a conceptual diagram showing an example of a conventional duct type ventilation system.

Figure 2 is a conceptual diagram showing another example of a conventional duct type ventilation system.

3 is a conceptual diagram illustrating a conventional ductless blowing system.

4 is a cross-sectional view showing an example of a ductless blower used in a conventional ductless blowing system.

5 is a cross-sectional view showing an example of a ductless blower having a conventional turning blower head.

FIG. 6 is a partially enlarged sectional view showing that the ductless blower shown in FIG. 4 receives a large air resistance by the inclined inner end of the head when the direction of the blowing head is changed.

7 is a cross-sectional view of the ductless blower according to the present invention.

8 is an enlarged partial cross-sectional view of the ductless blower according to the present invention.

9 is a cross-sectional view illustrating an example in which a guide blade is mounted on an inner circumferential surface of a blowout nozzle unit as another embodiment of a ductless blower according to the present invention.

Explanation of reference numerals for main parts

20: ductless blower 22: casing

24: blow out nozzle 26: blowing fan

28: acute space portion 30, 31: partial spherical surface

32: one end of the tube 34: the other end of the tube

36: tube 38: guide blade

The ductless blower according to the present invention, as shown in Fig. 7, generally the both ends of the hollow cylindrical and one end of the inner peripheral surface forming a partial spherical surface (30); A ejection nozzle part 24 which is rotatable in contact with a partial spherical surface 30 formed at one end of the casing; And in the ductless blower comprising a blower fan (26) coaxially mounted in the housing to blow the wind toward the blowout nozzle, having a diameter of approximately the same as the inner diameter of the casing 32 is fixed to the inner circumferential surface of the casing and the other end 34 is characterized in that the tube 36 of the stretchable material fixed to the casing inner end of the ejection nozzle portion is further added. According to the present invention, the ductless blower to which the tube 36 is added as described above, even if the opening nozzle 24 is bent in the up-down or left-right direction as shown in FIG. Since the acute angle of the inner circumferential surface of the casing at the inner end of the ejection nozzle part is prevented, the problem of lowering the ejection performance, ejection noise and vibration of the blower fan as described above is solved.

9 is a configuration capable of compensating for the reduction of the air blow-out length according to the angle change of the blow-out nozzle unit as an embodiment for achieving another object of the present invention. That is, when the angle is adjusted to a posture (bending position) that does not match the axial direction of the casing, the air blown out from the blower fan 26 is blown against the inner wall surface of the blowout nozzle with the angled angle so that the air blowout length In the above embodiment, the guide blade 38 having a predetermined height is vertically inclined at equal intervals on the inner circumferential surface of the ejection nozzle part to solve this problem. The guide blade 38 serves to allow the air blown out of the blower fan to be rotated in a constant direction (inclined direction of the blade) while passing through the blowout nozzle so as to be blown out to a greater distance by its rotational force.

On the other hand, the above embodiment of the present invention is a body that is separated from the casing, the nozzle taking the premise of the structure to change the air blowing direction by flowing at an angle from the front end of the casing, the above-described guide blade 38 ) Can be installed as it is even in the case of a ductless blower having a structure in which the blowout nozzle unit and the casing are fixed in a straight line (for example, the ductless blower shown in FIG. 4), in which case the same effect as that described above, that is, Since the augmentation effect can be achieved, the guide blade 38 includes a hollow cylindrical casing 22 having generally open ends; An ejecting nozzle part 24 extending at one end of the casing; And even if it is mounted to a ductless blower structure having a blower fan (26) coaxially mounted inside the gasket to blow the wind toward the blowout nozzle portion is within the scope of the present invention Should be interpreted as belonging.

The ductless blowing fan according to the present invention can form a distal end portion of the casing in a partial spherical shape, while the engaging portion to the casing of the ejection nozzle part can flow in contact with the spherical inside of the spherical distal end portion of the casing. In the ductless blower having a spherical surface, the acute expansion and contraction tube 36 is mounted so that acute angle generation to the inner circumferential surface of the casing of the inner end of the ejecting nozzle part is eliminated even if the opening direction of the ejecting nozzle part is changed. Therefore, it is possible to provide a ductless blower that prevents excessive blowout static pressure and properly exerts the originally designed blower capacity, and reduces vibration and noise generation, and also has a predetermined height in the inclined direction on the inner circumferential surface of the blowout nozzle part. Air blowing in accordance with the angle change of the blowout nozzle part by vertically inserting the guide blade 38 It is possible to provide a ductless blower capable of compensating for the reduction in the delivery length, thereby greatly improving the performance of the conventional ductless blower.

Claims (3)

A casing 22 having a generally cylindrical shape having both ends opened and having an inner circumferential surface thereof as a partial spherical surface 30; An ejection nozzle part 24 having one end forming a partial spherical surface 31 and the other end opened so as to be in contact with the partial spherical surface formed at one end of the casing; And in the ductless blower comprising a blower fan (26) mounted coaxially with the casing in the casing to blow the wind toward the blowout nozzle, It has a diameter approximately equal to the inner diameter of the casing, and one end 32 is fixed to the inner circumferential surface of the casing and the other end 34 has an elastic material tube 36 fixed to the inner end of the casing of the ejection nozzle part. Ductless blower characterized in that The ductless blower according to claim 1, wherein a guide blade (38) having a predetermined height is placed on the inner circumferential surface of the ejection nozzle part at equal intervals in an inclined direction. A hollow cylindrical casing 22 having generally open ends; An ejecting nozzle part 24 extending at one end of the casing; In the ductless blower having a structure in which a blowing fan 26 is mounted coaxially to the inside of the housing to blow wind toward the blowout nozzle, the inclined direction or the like on the inner circumferential surface of the blowout nozzle unit. A ductless blower, characterized in that the guide blade 38 of the predetermined height is placed at intervals.