KR100781298B1 - Blower - Google Patents

Abstract

A ventilator is provided to reduce noise of a blower transmitted to the outside by forming a curved route from an air inlet hole to the blower using a partition member. A ventilator includes a case(110), a blower(130), an inverter(140), and a radiator(152). The case has a receiving part(111) and an air inlet hole to introduce air into the receiving part. The blower is arranged in the receiving part of the case and has a motor and an impeller connecting to the motor, and compresses the air flowing from the air inlet hole and blows the air to the outside of the receiving part. The inverter is arranged in the receiving part of the case and is electrically connected to the blower to control the speed of the impeller. The radiator is connected to a cooling water channel in the blower to cool the blower. The radiator is arranged between the air inlet hole and the blower. The radiator emits heat included in the cooling water heated through the cooling water channel to the air flowing from the air inlet hole.

Description

Blower {Blower}

The present invention relates to a blower, and more particularly, to a blower for compressing and blowing a large amount of air.

A blower is a machine that compresses and blows air, and is manufactured in various forms according to its use and the amount of air that can be compressed. Among them, a turbo blower blows a large amount of air at a relatively low pressure (0.3 to 1.3 bar), and is used for aeration or powder transfer of a sewage treatment plant. Such a turbo blower generates a considerable amount of heat in the motor and the inverter when it is driven, and there is a fear that the heat is broken by the heat. Therefore, the turbo blower is provided with a cooling device for cooling the motor and the inverter. The chiller includes an air-cooled chiller using air and a water-cooled chiller using cooling water, depending on the medium used for cooling. A water-cooled chiller is mainly used for a device that generates a large amount of heat such as a large turbo blower. 1 shows an example of a turbo blower equipped with a water cooling device.

Referring to FIG. 1, the turbo blower 100 includes a case 10, a blower 20, an inverter 30, and a cooling device.

An accommodating part 11 is formed inside the case 10, and an air inlet 12 is formed in the side of the case 10. The blower 20 is installed in the accommodating part 11 of the case, and has a motor (not shown) and an impeller (not shown). The impeller is connected to the motor and rotates together when the motor is driven. Impeller is a known configuration, various kinds such as the impeller disclosed in Japanese Patent Laid-Open No. 2002-0035927 may be employed. In addition, the blower 20 is provided with a water jacket (not shown) through which cooling water flows. The inverter 30 has a water jacket and is installed in the accommodating part 11 of the case 10. The inverter 30 is electrically connected with the motor. The inverter 30 adjusts the rotational speed of the motor to control the amount and speed of air blown by the blower 20. The cooling apparatus includes a storage tank (not shown), a pump (not shown), a cooling passage 40, and a cooling tower (not shown). The storage tank is installed outside the case 10, and cooling water for cooling the blower 20 and the inverter 30 is stored therein. The pump is connected to the storage tank and is installed outside the case 10. The cooling passage 40 flows cooling water therein. The cooling passage 40 interconnects the water jacket and the pump of the blower 20 and the inverter 30. The cooling tower is installed outside the case 10, and is connected to the water jacket and the storage tank of the blower 20 and the inverter 30 by the cooling passage 40.

When the turbo blower 100 configured as described above is operated, heat is generated in the blower 20 and the inverter 30. When the cooling apparatus is operated to remove the generated heat, the cooling water is supplied to the water jackets of the blower 20 and the inverter 30 through the cooling passage 40, and then flows along the water jacket to blow the blower 20 and the inverter ( 30) to cool. Cooling water heated along the water jacket passes through the cooling tower to cool, and then enters the storage tank.

However, as described above, the turbo blower 100 includes a cooling tower for cooling the cooling water, and in general, the cooling tower is complicated in structure and bulky. Therefore, the size of the turbo blower 100 is large, there is a problem in that a large cost is consumed to produce a cooling tower.

On the other hand, the cooling water may be cooled by using a radiator rather than a large cooling tower, but in this case, a fan must be provided to quickly cool the cooling water passing through the radiator. Therefore, the configuration of the turbo blower 100 is complicated, making the production difficult, there is a problem that the energy loss for driving the fan occurs.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a blower having a simple structure, an efficient cooling of a blower and an inverter, and an improved structure to reduce manufacturing and maintenance costs. To provide.

In order to achieve the above object, the blower according to the present invention is provided with a receiving portion, a case having an air inlet for introducing air into the receiving portion, disposed in the receiving portion of the case, connected to the motor and the motor And an impeller installed so as to be rotatable, the blower compressing the air flowing from the air inlet and blowing to the outside of the accommodating part, and disposed in the accommodating part of the case, and electrically connected to the blower. An inverter for controlling the rotational speed and a cooling water path installed in the blower for cooling the blower, and disposed between the air intake port and the blower on a flow path of air introduced from the air intake port, Air that flows from the air inlet through the heat contained in the heated cooling water It characterized in that it comprises a radiator to discharge.

According to the present invention of the above configuration, it is possible to cool the cooling water by using the air introduced into the blower. Therefore, the structure of the blower is simplified and the manufacturing and maintenance cost of the blower is reduced. In addition, it is possible to reduce the noise generated in the blower.

2 is a schematic cross-sectional view according to an embodiment of the present invention.

Referring to FIG. 2, the blower 200 according to the present embodiment includes a case 110, a partition member 120, a blower 130, an inverter 140, a cooling device 150, and a filter ( 160 and 161, and a soundproof cover 170.

The case 110 has a receiving portion 111 formed therein. On the left side and the right side of the case 110, an air inlet 112 and an auxiliary air inlet 113 for introducing air into the accommodating part 111 of the case are respectively formed therethrough. In addition, a blower hole 114 through which the blower tube 132 of the blower 130 to be described later is fitted is formed in the upper side of the case 110.

The partition member 120 is for separating the receiving portion 111 of the case 110 into a plurality of space portions. The partition member 120 is installed in the accommodating part 111 and includes a first blocking member 121, a second blocking member 122, and a third blocking member 123. The first blocking member 121 is installed in the receiving portion 111 in the horizontal direction. An inlet hole 124 is formed through the right edge portion of the first blocking member 121. The second blocking member 122 is installed in the receiving portion 111 in the vertical direction. Both ends of the second blocking member 122 are coupled to the case 110, and the left side of the second blocking member 122 is coupled to the right end of the first blocking member 121. Outflow hole 125 is formed through the second blocking member 122 through. The third blocking member 123 includes a parallel portion 123a extending in the horizontal direction from the upper side of the air suction port 112 and a vertical portion 123b extending downward from the end of the parallel portion 123a. The vertical portion 123b is coupled to the left end of the first blocking member 121.

By the partition member 120 installed as described above, the accommodating portion 111 of the case is separated into a first space portion A, a second space portion B, and a third space portion C. FIG. . An air suction port 112 is disposed in the first space A. As shown in FIG. The second space portion B is disposed above the first space portion A, and communicates with the first space portion A through the inflow hole 124. The auxiliary air inlet 113 is disposed in the third space C. The third space portion C is disposed on the right side of the first space portion A and the second space portion B. FIG. The third space portion C communicates with the second space portion B through the outlet hole 125.

The blower 130 is for compressing the air flowing from the air inlet 112 and blowing the air outside the accommodating part 111. The blower 130 is installed in the second space portion B, and has a motor (not shown) and an impeller (not shown). The motor is electrically connected to a power supply (not shown). The impeller is connected to the motor and rotates with the motor when the motor is driven. When the impeller is rotated, air flows into the air suction part 131 of the blower 130 and is compressed, and then to the outside of the receiving part 111 through the blower tube 132 of the blower 130 fitted into the blower hole 114. It is blown. In addition, the blower 130 is provided with a cooling water for cooling the blower 130, that is, a water jacket (not shown). The water jacket is arranged around the motor and the impeller. The water jacket is connected to a cooling passage 151 to be described later, and a coolant for cooling the blower 130 flows therein. Since the blower 130 is a known configuration already disclosed in the registered patent No. 0572850, detailed description thereof will be omitted.

The inverter 140 is installed in the third space part C and is electrically connected to the motor. The inverter 140 controls the amount and speed of air blown by the blower 130 by adjusting the rotational speed of the motor. In addition, the inverter 140 is provided with a coolant for cooling the inverter 140, that is, a water jacket. The water jacket is connected to the cooling passage 151 to be described later, the cooling water flows therein.

The cooling device 150 is for cooling the blower 130 and the inverter 140. In particular, the cooling device 150 in this embodiment includes a radiator 152, a storage tank 153, a pump 154 and a cooling passage 151. The radiator 152 is installed in the first space A, and cools the heated coolant through the water jacket. Since the radiator 152 is a well-known configuration already disclosed in Patent No. 0572850, detailed description thereof will be omitted. The storage tank 153 is disposed in the first space A, and stores the coolant. The pump 154 is disposed in the first space A, and pumps the coolant stored in the storage tank 153 to connect the water jacket of the blower 130 and the inverter 140 and the cooling passage 151 to be described later. Circulate accordingly. The cooling passage 151 is a pipe through which cooling water flows, and is connected to the water jacket of the blower 130 and the inverter 140. In addition, the cooling flow path 151 connects the water jacket of the radiator 152 and the storage tank 153, the storage tank 153 and the pump 154, the pump 154 and the blower 130, and the inverter 140 to each other. do.

The filters 160 and 161 are for purifying air flowing into the case accommodating part 111. The filters 160 and 161 block the air inlet 112 and the auxiliary air inlet 113 and are installed in the case 110, respectively.

Soundproof cover 170 is for blocking the noise generated in the blower (130). The soundproof cover 170 is coupled to the vertical portion 123b of the third blocking member 123.

Hereinafter, an example of a process of blowing using the blower 200 configured as described above will be described.

When the blower 130 is operated, a negative pressure is formed in the accommodating part 111 of the case, and external air is introduced into the accommodating part 111 through the air inlet 112 and the auxiliary air inlet 113. . The air introduced into the first space A through the air inlet 112 flows along the third blocking member 123 and the first blocking member 121, and passes through the radiator 152. It is introduced into the second space portion B through the ball 124. Air introduced into the third space portion C through the auxiliary air inlet 113 flows along the second blocking member 122, passes through the inverter 140, and then passes through the outlet hole 125. It flows into the space portion B. As such, the air introduced into the second space portion B is introduced into the air intake 131 of the blower 130 and then blown to the outside through the blower pipe 132. In this case, the amount and speed of air blown by the blower 130 may be adjusted using the inverter 140.

Meanwhile, the blower 130 and the inverter 140 that are heated when the blower 200 is driven are cooled by the cooling device 150 as follows. When the pump 154 is operated, the cooling water stored in the storage tank 153 is supplied to the cooling passage 151. The cooling water supplied to the cooling passage 151 passes through the water jacket of the blower 130 and the inverter 140. During this process, heat exchange occurs between the blower 130 and the inverter 140 and the coolant so that the heat generated in the blower 130 and the inverter 140 is transferred to the coolant, and as a result, the blower 130 and the inverter 140 ) Cooled by coolant. The coolant heated through the water jacket of the blower 130 and the inverter 140 is supplied to the radiator 152. While the cooling water passes through the radiator 152, heat exchange occurs between the cooling water and the air flowing through the first space A, and as a result, the cooling water is cooled by the air.

At this time, since the air flows quickly through the first space A due to the negative pressure generated by the blower 130 as described above, heat exchange occurs actively between the cooling water and the air, and as a result, the cooling efficiency of the cooling water is increased. The coolant thus cooled is introduced into the storage tank 153 again, and then the above-described process is repeated to cool the blower 130 and the inverter 140.

In addition, while the air introduced into the third space portion C from the auxiliary air intake 113 passes through the inverter 140 and flows into the second space portion B, heat of the inverter 140 is released into the air. As a result, the inverter 140 is further cooled.

As described above, in the blower 200 according to the present embodiment, the radiator 152 is installed between the air inlet 112 and the blower 130 on the flow path of the first space A, that is, the air. . Therefore, the cooling water can be efficiently cooled by using the flow of air flowing from the air suction port 112 to the blower 130. As a result, the cost of having a large cooling tower or a fan can be reduced, and the structure of the blower is simplified. In addition, since the air introduced from the auxiliary air suction port 113 passes through the inverter 140 and flows into the second space portion B, the cooling efficiency of the inverter 140 is increased.

In addition, the path from the air suction port 112 to the blower 130 is formed long by the partition member 120 in a curved shape. Therefore, the path from the blower 130 to the outside of the noise transmitted to the outside is long, and as a result, the intensity of the noise transmitted to the outside is weakened.

Meanwhile, in the present embodiment, the receiving portion 111 of the blower 200 is configured to be separated into three space portions, but as shown in FIG. 3, the receiving portion of the blower is divided into two space portions, and two impellers are provided. You may comprise so that it may be provided.

Referring to FIG. 3, the blower 200A according to the present embodiment includes a case 110A, a partition member 120A, a blower 130A, an inverter 140, a cooling device 150, and a filter ( 160 and a soundproof cover 170. Hereinafter, the differences from the above-described embodiment will be described.

The case 110A includes a receiving portion 111. On the left side of the case is formed an air inlet 112 for introducing air into the case receiving portion. In addition, a pair of blow holes 114 into which the blow pipe 132 of the blower 130A mentioned later is fitted is formed in the upper side surface of a case.

The partition member 120A is for separating the accommodating portion 111 of the case into a plurality of isolated space portions. The partition member 120A is installed in the receiving portion 111 and includes a first blocking member 121 and a third blocking member 123. The first blocking member 121 is disposed in the transverse direction in the receiving portion 111, the right end of the first blocking member 121 is coupled to the case 111. In addition, a pair of inflow holes 124 is formed through the first blocking member 121. The third blocking member 123 includes a parallel portion 123a extending in the horizontal direction from the upper side of the air suction port 112 and a vertical portion 123b extending downward from the end of the parallel portion 123a. The vertical portion 123b is coupled to the left end of the first blocking member 121.

By the partition member 120A provided in this way, the accommodating portion 111 of the case is separated into a first space portion A and a second space portion B. FIG. An air inlet 112 is disposed in the first space A, and a radiator 152 and an inverter 140 are installed. The second space portion B is disposed above the first space portion A, and communicates with the first space portion A through the pair of inflow holes 124.

The impeller is provided with a pair. Each impeller is connected to the motor, and during the rotation of the impeller compresses the air flowing through the air intake 131 of the blower (130A) and then blows the air outside the receiving portion (111).

When the blower 130A of the blower 200A configured as described above is operated, a negative pressure is generated in the second space portion B, and as a result, the air inlet 112 is moved from the air inlet 112 to the first space portion A. FIG. The introduced air is introduced into the second space portion B through the inlet hole 124. In this way, the coolant passing through the radiator 152 and the inverter 140 are cooled by the air flowing in the first space A. FIG.

As mentioned above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the technical idea of the present invention. It is obvious.

For example, in this embodiment, the storage tank and the pump are configured to be disposed in the housing of the case, but the storage tank and the pump may be configured to be installed outside the case.

1 is a schematic schematic cross-sectional view of a conventional turbo blower.

2 is a schematic cross-sectional view of a blower according to an embodiment of the present invention.

3 is a schematic cross-sectional view of a blower according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

200, 200 A ... blower 110, 110 A ... case

111.Receiving part 120,120A ... Partition member

130, 130 A ... Blower 140 ... Inverter

150 Cooling system 151 Cooling flow path

152 ... radiator 160,161 ... filter

170 ... soundproof cover A ...

B ... space 2 C ... space 3

Claims (3)

A case having an accommodating part and an air inlet for introducing air into the accommodating part; A blower disposed in the accommodating part of the case and having a motor and an impeller connected to the motor to be rotatable, for compressing air introduced from the air inlet and blowing the air out of the accommodating part; An inverter disposed in the accommodating part of the case and electrically connected to the blower to control a rotational speed of the impeller; And It is connected to the cooling water passage installed in the blower to cool the blower, and is disposed between the air inlet and the blower on the flow path of the air flowing from the air inlet, and is included in the cooling water heated through the cooling water passage. And a radiator for dissipating heat into the air introduced from the air inlet. The method of claim 1, The accommodation portion is divided into a plurality of space portions including a first space portion in which the air intake port is disposed and a second space portion separated from the first space portion, and air flows from the first space portion to the second space portion. Further comprising a partition member is formed through the inlet hole for flow, And the radiator is disposed in the first space part and the blower is disposed in the second space part so that air introduced through the air inlet is introduced into the blower through the radiator. The method of claim 2, The case is provided with a secondary air inlet for penetrating the air into the receiving portion, By the partition member, the accommodating portion is separated into the first space portion, the second space portion, the third space portion separated from the first space portion and the second space portion and the auxiliary air suction opening is arranged. , The partition member is formed with an outlet hole for air to flow from the third space portion to the second space portion, And the inverter is disposed in the third space part.

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