TWM545226U - An air purifier - Google Patents

Abstract

The present invention relates to an air purifier comprising: a base, base comprising: serial a plurality of axis fans; an air inlet of base; and an air outlet of base; and a nozzle, nozzle mounted on a base, nozzle comprising: an air inlet of nozzle; and an air outlet of nozzle.

Description

Air purifier

This case relates to an air purifier, especially an air purifier using an axial flow fan with good pressure loss resistance.

Generally, the air purifier uses an axial fan, but the axial fan anti-filter has a poor pressure loss. After the filter has a pressure loss, the clean air volume will be reduced and needs to be solved.

The main purpose of this case is to provide an air purifier, especially an air purifier using an axial flow fan with good pressure loss resistance.

In order to achieve the above object, the air purifier of the present invention is a more general implementation, comprising: a base having: a plurality of axial fans connected in series; a base air inlet for the inlet of the suction airflow; and a base The air outlet is used as an outlet for the discharge airflow; and a nozzle is mounted on the base, the nozzle is linear in front view, and has a nozzle airflow inlet at the nozzle, which is an opening for receiving the base a jet airflow; a nozzle airflow outlet located at the nozzle, which is a smaller opening than the nozzle airflow inlet, and a Bernoulli's principle, which is smaller than the nozzle airflow inlet opening, can increase the airflow velocity for ejecting the airflow; a wall end; a second wall end, the first wall end engaging a first closing surface, and the second wall end engaging a The second closed surface is used to block the flow of air; and a Coanda surface, close to the nozzle air outlet, to create a Coanda effect to increase the overall flow of the final output airflow.

In order to achieve the above object, another generalized embodiment of the air purifier of the present invention comprises: a pedestal having: a plurality of axial flow fans connected in series; a pedestal air flow inlet for inlet of the suction airflow; And a pedestal air outlet for the outlet of the blasting air stream; and a nozzle, the nozzle is mounted on the pedestal, the nozzle is annular in front view, and has a nozzle airflow inlet, located at the nozzle, for an opening, The nozzle airflow outlet is located at the nozzle, which is a smaller opening than the nozzle airflow inlet, and the Bernoulli's principle, which is smaller than the nozzle airflow inlet, can increase the airflow speed for a first air wall end; a second wall end, the first wall end is joined to the second wall end for airflow, and the nozzle is formed into an annular hollow, and most of the central portion is hollow, and can pass light and airflow. Circulation; and a Coanda surface, close to the nozzle airflow outlet to create a Coanda effect to increase the overall flow of the final output airflow

10, 13, 20, 23‧‧‧ Air Purifier

11, 14, 21, 24‧‧‧ Pedestal

12, 15, 18, 19, 22‧ ‧ nozzle

25a-25b‧‧‧Two nozzles

110a-110b, 140a-140b, 210a-210b, 240a-240b‧‧‧ series two axial fans

111, 141, 211, 241‧‧ ‧ pedestal air inlet

112, 142, 212, 242‧‧‧ pedestal air outlet

113, 143, 213, 243‧‧ ‧ filter

121, 151, 181, 191, 221, 251‧‧ ‧ nozzle air inlet

122, 152, 182, 192‧‧‧ nozzle air outlet

123, 153, 183, 193, 223‧‧‧ first wall end

124, 154, 184, 194, 224‧‧‧ second wall end

125, 225‧‧‧ first closed face

126, 226‧‧‧ second closed surface

127, 157, 187, 197, 227‧‧ ‧ Coanda surface

160‧‧‧Axial fan

161‧‧‧Axial fan airflow outlet

162‧‧‧Axial fan air inlet

163‧‧‧Axial fan blades

164‧‧‧Axial fan motor

170‧‧‧Inline two axial fans

171a-171b‧‧‧Inline two axial fan airflow outlets

172a-172b‧‧‧Inline two axial fan airflow inlets

173a-173b‧‧‧Inline two axial fan blades

174a-174b‧‧‧Inline two axial fan motors

222a-222b‧‧‧Two nozzle airflow outlet spaces

252a-252b‧‧‧Two nozzle airflow outlets

253a-253b‧‧‧Two first wall ends

254a-254b‧‧‧Two second wall ends

257a-275b‧‧‧Two Coanda surfaces

Fig. 1 is a schematic view showing an embodiment of a linear nozzle when the air cleaner is facing the front view.

Fig. 2 is a schematic view showing an embodiment of the annular nozzle when the air cleaner is in front of the present invention.

Figure 3 is a schematic view of an embodiment of the axial flow fan of the present invention.

Figure 4 is a schematic view of an embodiment of two axial flow fans connected in series.

Figure 5 is a plot of air volume and static pressure.

Figure 6 is a schematic view of an embodiment of a slit nozzle in a tapered region of the present invention.

Figure 7 is a schematic view of an embodiment of a slit nozzle in the distance region of the present case.

Figure 8 is a schematic diagram of a plurality of spatial embodiments of the nozzle of the present invention.

Figure 9 is a schematic illustration of a plurality of nozzle embodiments of the present invention.

Some embodiments embodying the features and advantages of the present invention are described in detail in the following description. It should be understood that the present invention can be varied in different aspects without departing from the scope of the present invention, and the description and drawings are for illustrative purposes, and are not structurally limiting.

In one aspect, please refer to FIG. 1 . FIG. 1 is a schematic view showing an embodiment of the linear nozzle in the case of the air cleaner of the present invention. As can be seen from FIG. 1 , an air cleaner 10 includes: a base 11 having a series of two axial fans 110a-110b for drawing inflow and jetting air; a pedestal inlet 111 for inlet as a suction stream; a screen 113; and a pedestal outlet 112 for As the outlet of the jet stream; and a nozzle 12, the nozzle 12 is mounted on the base 11, the nozzle 12 is linear in front view, and has a nozzle air inlet 121 located at the nozzle 12 as an opening for receiving the base The jet stream of the air outlet 112; a nozzle air outlet 122, located at the nozzle 12, is a smaller opening than the nozzle air inlet, and the Bernoulli's principle, which is smaller than the nozzle air inlet 121, can increase the air velocity. For ejecting airflow; a first wall end 123; a second wall end 124, the first wall end 123 engaging a first closing surface 125, and the second wall end 124 engaging a second closing surface 126 for blocking airflow Pass; and a Coanda surface (Coandasurface) 127, which is close to the gas flow outlet nozzle 122 for generating a Coanda effect (Coanda effect), the final output stream to increase the overall flow.

In another aspect, please refer to FIG. 2, which is a schematic view of an annular nozzle embodiment in the case of the air cleaner of the present invention. As can be seen from FIG. 2, an air cleaner 13 includes: a base 14 The utility model has a series of two axial flow fans 140a-140b for sucking airflow and ejecting gas a flow; a pedestal airflow inlet 141 for use as an inlet for the suction airflow; and a pedestal airflow outlet 142 for exiting the effluent airflow; and a nozzle 15 mounted on the susceptor 14, the nozzle 15, The front view is a ring shape having a nozzle air flow inlet 151 located at the nozzle 15 as an opening for receiving the jet airflow of the pedestal airflow outlet 142; a nozzle airflow outlet 152 located at the nozzle 15 as a nozzle airflow inlet The opening of the small, Bernoulli's principle, which is smaller than the opening of the nozzle air inlet 151, can increase the airflow speed for ejecting the airflow; a first wall end 153; and a second wall end 154, the first wall The end 153 engages the second wall end 154 for airflow, and the nozzle is annularly hollow, the central portion of which is hollow and can be circulated by light and airflow; and a Coanda surface 157 which is close to the nozzle airflow. The outlet 152 is used to generate a Coanda effect to increase the overall flow of the final output airflow.

Figure 3 is a schematic view of an axial flow fan embodiment of the present invention. The axial flow fan 160 is configured to take in an air flow and a discharge air flow. The air flow fan has an axial flow fan air outlet 161; an axial flow air flow inlet 162; and an axial flow fan blade. 163; and an axial fan motor 164.

Figure 4 is a schematic view of an embodiment of two axial flow fans connected in series, two axial flow fans 170 connected in series for sucking air flow and discharging air flow having: two axial flow fan air outlets 171a-171b connected in series; Axial fan airflow inlets 172a-172b; two axial fan blades 173a-173b in series; and two axial fan motors 174a-174b in series.

Please refer to Fig. 5 for the air volume and static pressure diagram. The air purifier Q2 of the air purifier using two axial flow fans in series under the same filter pressure loss P is larger than the clean air purifier using a single axial fan. Air volume Q1.

Figure 6 is a schematic view of an embodiment of a slit nozzle in the tapered region of the present invention. The nozzle 18 has a nozzle air inlet 181 located at the nozzle 18 as an opening for receiving the base. a jet stream exiting the air outlet; a nozzle air outlet 182 located at the nozzle 18, which is a smaller opening than the nozzle air inlet, and a Bernoulli's principle, which is smaller than the nozzle air inlet 181. Increasing the airflow speed for ejecting the airflow; a first wall end 183; and a second wall end 184; and a Coanda surface 187 that is adjacent to the nozzle airflow outlet 182 for producing a Coanda effect (Coanda) Effect), increasing the overall flow of the final output airflow.

Figure 7 is a schematic view of a slit nozzle embodiment of the present embodiment, the nozzle 19 having a nozzle air flow inlet 191 located at the nozzle 19 as an opening for receiving the jet airflow of the pedestal air outlet; The air outlet 192 is located at the nozzle 19 and is a slit opening in the shape of the nozzle which is smaller than the inlet of the nozzle. According to the Bernoulli's principle, the opening is smaller than the nozzle inlet 191, and the airflow speed can be increased to eject the airflow. a first wall end 193; and a second wall end 194; and a Coanda surface 197 that is adjacent to the nozzle airflow outlet 192 for generating a Coanda effect, increasing the overall output airflow overall flow.

In another aspect, please refer to FIG. 8. FIG. 8 is a schematic diagram of a plurality of spatial embodiments of the nozzle of the present invention. As can be seen from FIG. 8, an air cleaner 20 includes: a base 21 having: a series of two axial fans 210a-210b for drawing inflow and jetting air; a pedestal air inlet 211 for inlet as a suction airflow; and a pedestal air outlet 212 for exiting the blasting airflow; And a nozzle 22, the nozzle 22 is mounted on the base 21, the nozzle 22 is linear in front view, and has a nozzle airflow inlet 221 located at the nozzle 22 as an opening for receiving the jet airflow of the base airflow outlet 212. Two nozzle airflow outlet spaces 222a-222b, located at the nozzle 22, are smaller than the nozzle airflow inlet opening, and the law of whitening (Bernoulli's a smaller opening than the nozzle air inlet 221, which can increase the airflow speed for ejecting the airflow; a first wall end 223; a second wall end 224, the first wall end 223 engaging a first closed surface 225, The second wall end 224 engages a second closing surface 226 to block airflow; and a Coanda surface 227 that is adjacent to the nozzle airflow outlet 222a for creating a Coanda effect and increasing the final output airflow. Overall traffic.

In the other three aspects, please refer to FIG. 9 , which is a schematic diagram of a plurality of nozzle embodiments of the present invention. As can be seen from FIG. 9 , an air cleaner 23 includes: a base 24 having: a series connection An axial flow fan 240a-240b for drawing in air and a jet stream; a pedestal air inlet 241 for receiving as an intake air stream; a screen 243; and a pedestal air outlet 242 for ejecting air And two nozzles 25a-25b, two nozzles 25a-25b mounted on the base 24, two nozzles 25a-25b, annular in front view, having: two nozzle airflow inlets 251a-251b, located in two The nozzles 25a-25b are an opening for receiving the jet airflow of the base airflow outlet 242; the two nozzle airflow outlets 252a-252b are located at the two nozzles 25a-25b, which are smaller than the nozzle airflow inlet, and are white The Bernoulli's principle, which is smaller than the openings of the two nozzle airflow inlets 251a-251b, can increase the airflow speed for ejecting the airflow; the two first wall ends 253a-253b; and the two second wall ends 254a-254b , two first wall ends 253a-253b Two second wall ends 254a-254b are used for airflow, and the nozzle is formed as an annular hollow, and most of the central portion is hollow, which can be circulated by light and airflow; and two Coanda surfaces 257a-257b It is adjacent to the two nozzle airflow outlets 252a-252b for generating a Coanda effect, increasing the overall flow of the final output airflow.

The main purpose of this case is to provide an air purifier, especially an air purifier using an axial flow fan with good pressure loss, and using two parallel shafts under the same filter pressure loss. The clean air volume of the air cleaner of the flow fan is greater than the clean air volume of the air cleaner using a single axial flow fan, and the fan of this case is of great industrial value and is applied according to law.

This case has been modified by people who are familiar with this technology, but they are all protected by the scope of the patent application.

10‧‧‧Air Purifier

11‧‧‧Base

12‧‧‧ nozzle

110a-110b‧‧‧Two axial fans in series

111‧‧‧Base air inlet

112‧‧‧Base air outlet

113‧‧‧ Filter

121‧‧‧Nozzle air inlet

122‧‧‧Nozzle air outlet

123‧‧‧First wall end

124‧‧‧second wall end

125‧‧‧ first closed face

126‧‧‧Second closed face

127‧‧‧Coanda surface

Claims (11)

An air cleaner comprising: a base for ejecting airflow, comprising: a plurality of axial fans connected in series; a base airflow inlet; a screen; and a base airflow outlet; and a nozzle The nozzle is mounted on the base, and includes: a nozzle airflow inlet, an opening for receiving the jet airflow of the base; and a nozzle airflow outlet, which is a smaller opening than the nozzle airflow inlet for ejecting airflow. The air cleaner according to claim 1, wherein the nozzle comprises: a first wall end; a second wall end; a first closing surface, the first wall end engaging the first closing surface, Blocking airflow; and a second closed surface that engages the second closed surface to prevent airflow. The air cleaner according to claim 1, wherein the nozzle comprises: a first wall end; and a second wall end, the first wall end engaging the second wall end for airflow, and forming The nozzle is annular and hollow, and most of the central area is hollow, which can be circulated through light and air. The air purifier according to claim 1, wherein the nozzle comprises: a Coanda surface adjacent to the nozzle airflow outlet for generating a Coanda effect. The air purifier according to claim 1, wherein the nozzle airflow outlet is a tapered region A field slit for ejecting airflow. The air purifier according to claim 1, wherein the nozzle airflow outlet is a slotted portion for ejecting airflow. The air purifier according to claim 1, wherein the pedestal airflow inlet may be one or more. The air purifier according to claim 1, wherein the pedestal airflow outlet may be one or more. The air cleaner according to item 1, wherein the nozzle airflow inlet may be one or plural. The air purifier according to claim 1, wherein the nozzle air outlet is partitioned into a plurality of spaces. The air cleaner according to claim 1, wherein the nozzles may be one or plural.