KR101708718B1 - Impeller agitator - Google Patents

Abstract

The present invention relates to a fluid agitator and, more specifically, to a fluid agitator which can forcibly circulate fluid introduced into a space between a storage tank and the agitator by radially protruding and forming a second agitating wing on a lower side of an agitator provided on an upper surface of a first agitating wing.

Description

Impeller agitator

The present invention relates to a fluid agitating device, and more particularly, to a fluid agitating device in which a second agitating blade is radially protruded from a bottom surface of an agitator having a first agitating blade on an upper surface thereof, 2 stirring blade can be forcibly circulated and the second stirring blade is formed in a hemispherical shape on one side and the other surface is formed as a wing body having a guiding surface inclined from the center toward the outer end of the agitator, The inclined surface inclined upward from the inner end to the outer end is provided, so that the agitator can forcibly circulate a large amount of fluid during rotation, and the second stirring vane is projected and withdrawn by the magnetic force at the bottom of the agitator. Thereby preventing the overload from being generated in the motor for rotating the stirrer to the maximum, The first relates to a fluid stirrer using a stirring blade 2 to be circulated to force the fluid flowing into the space.

Generally, a fluid agitating device is a device capable of forcibly circulating a fluid stored in a storage tank.

At this time, the fluid circulating in the storage tank by the fluid agitator forcibly refers to foods that are provided in liquid form such as cold water, milk, or milk. Thus, the fluid agitator is installed in a slush refrigerator or the like.

Fig. 1 shows a slush cooler equipped with a conventional fluid agitating device. In Fig. 1, reference numeral 1 denotes a housing 1.

A lid 5 is coupled to the upper surface of the housing 1 by means of a cap and a storage tank 2 in which the fluid is stored.

At this time, a switch is provided at the upper end of the housing 1 so that when the lid 5 is coupled to the upper end of the housing 1, the switch is turned on so that the motor 60 installed inside the housing 1 can be operated .

A coolant pipe 3 is installed on the outer circumferential surface of the storage tank 2 so that the coolant supplied from the coolant pipe 3 can be used to store the fluid in the storage tank 2 at a low temperature.

The stirrer 80 is installed in the storage tank 2 inside the housing 1 to rotate by receiving the rotational force of the motor 60.

A mounting hole 4 is provided on the bottom surface of the storage tank 2 in which the stirrer 80 is installed and a coupling portion 10 is provided to penetrate the mounting hole 4.

The coupling portion 10 includes a body portion 12 having a shaft hole 11 through which the rotation shaft 40 passes and a bearing housing 30 screwed to the body portion 12.

At this time, the bearing housing 30 also has a shaft hole through which the rotary shaft 40 passes.

A description will now be given of a process of mounting the coupling unit 10 constructed as described above on the bottom surface of the storage tank 2. Firstly, the bearing housing 30 through which the rotation shaft 40 passes is positioned directly below the mounting hole 4 , The body portion 12 is positioned inside the storage tank 2 so as to be positioned on the same vertical line as that of the bearing housing 30.

The bearing housing 30 is screwed to the bottom surface of the body portion 12 so that the rotary shaft 40 passing through the bearing housing 30 passes through the shaft hole 12 of the body portion 12, And the engaging portion 10 is fixedly coupled to the bottom surface

The coupling pulley 50 is axially coupled to the lower end of the rotary shaft 40 in a state where the coupling portion 10 through which the rotary shaft 40 penetrates is installed in the storage tank 2 and is separated from the coupling pulley 50 The connecting pulley 50 and the driving pulley 62 are connected to each other by the belt 70 in a state where the driving pulley 62 is axially fixed to the motor shaft 61 of the motor 60 in the housing 1. [

Accordingly, the rotational force of the motor 60 is transmitted to the connecting pulley 50 installed in the rotating shaft 40, and the rotational force of the connecting pulley 50 is transmitted to the stirrer 80 coupled to the upper end of the rotating shaft 40 .

The stirrer 80 is formed in a disc shape having a shaft hole, and a stirring wing 81 is radially protruded from the upper surface of the stirrer 80.

The agitator 80 provided with the agitating blades 81 is installed in the storage tank 2 so as to be installed in the rotating shaft 40 connected to the motor 60, So that the fluid stored in the storage tank 2 is forcibly circulated while being rotated in the rotating direction.

However, a problem with the conventional fluid stirring apparatus is that the stirrer 80 provided with the stirring vane 81 at the upper end of the coupling portion 10 through which the rotating shaft 40 penetrates is installed inside the storage tank 2, The fluid introduced into the space 2a between the agitator 80 and the agitator 80 can not be circulated even when the agitator 80 is rotated.

The fluid introduced into the space 2a between the storage tank 2 and the stirrer 80 is not circulated even when the stirrer 80 is rotated and therefore the space 2a is formed between the storage tank 2 and the stirrer 80, So that the fluid contained in the storage tank 2 is liable to be damaged due to the sediment.

In addition, since the agitator 80 can not circulate the fluid flowing into the space 2a, sediments are accumulated between the spaces 2a, and the sediment causes a problem of frequently cleaning the inside of the storage tank 2 .

The rotating shaft 40 is not smoothly rotated due to the sediment of the fluid accumulated in the space 2a, and the motor 60 for rotating the stirrer 80 is frequently damaged due to overload.

◆ Prior Art Documents ◆

Registered Utility Model No. 466108

In order to solve the above problems, according to the present invention, a second stirring blade is radially protruded from the bottom surface of the stirrer provided on the upper surface of the first stirring blade to forcibly circulate the fluid introduced into the space between the storage tank and the stirrer The second stirring blade is formed as a hemispherical shape on one side and the other side is formed as a wing body having an inclined guiding surface from the center toward the outer side of the agitator while the bottom surface of the wing body is inclined from the inner side to the outer side Since the inclined surface inclined upward is provided, the agitator can forcibly circulate a large amount of fluid during rotation, and the second agitating blades are combined and projected and withdrawn by the magnetic force at the bottom of the agitator, A fluid agitating device for preventing overload from occurring and for reducing power consumption The purpose is to provide.

According to an aspect of the present invention,

Wherein a rotating shaft which is rotated by receiving a rotating force of the motor is installed to penetrate the bottom surface of the storage tank and the stirrer is installed on the rotating shaft,

In the agitator,

A disk-shaped stirring body is formed,

A first stirring blade radially protruding from an upper portion of the stirring body,

A second stirring blade for circulating the fluid introduced into the space between the storage tank and the stirring body from the storage tank to the steel material is radially protruded from the bottom surface of the stirring body.

According to the present invention, the second stirring blade is radially protruded on the bottom surface of the agitator provided on the upper surface of the first stirring blade, so that the fluid introduced into the space between the storage tank and the agitator can be forcibly circulated, It is possible to prevent the fluid stored in the storage tank from being damaged due to the sediment.

The second stirring blade is formed in a hemispherical shape on one side and is formed as a wing body having an induction surface inclined from the center toward the outer end of the agitator on the other side, The fluid introduced into the space during the rotation of the agitator can be forced to circulate a large amount of fluid along the guiding surface and the inclined surface in the storage tank.

In addition, the second stirring blade can prevent the overload from being generated in the motor that rotates the agitator to the maximum, and can reduce the power consumption of the motor, The effect of forcibly circulating the fluid introduced into the space when the stirring wing draws out from the agitator can be expected.

1 is a sectional view showing a conventional fluid stirring device;
2 is a sectional view showing the fluid agitating device of the present invention.
3 is a perspective view showing a state in which the stirrer of the present invention is installed.
4 is a view showing an agitator of the present invention.
5 is a view showing another embodiment of a stirring blade of the stirrer of the present invention.
6 is a cross-sectional view showing another embodiment of a stirring blade of the stirrer of the present invention.
7 is a cross-sectional view showing another embodiment of the fluid stirring apparatus of the present invention of the present invention.
8 is a partially enlarged cross-sectional view showing the appearance and appearance means of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying FIGS. 2 to 8. FIG.

Prior to the description of the present invention, the same reference numerals are used for the same components as those of the prior art, and the description of the same reference numerals will be omitted.

According to the drawings,

Wherein the rotary shaft (40) rotated by receiving the rotational force of the motor (60) is installed to penetrate the bottom surface of the storage tank (2) and the stirrer (100) is installed on the rotary shaft (40) ,

The agitator (100)

A disk-shaped stirring body 110 is formed,

A first stirring blade 120 is radially protruded from an upper portion of the stirring body 110,

A second stirring blade 130 for circulating the fluid introduced into the space 2a between the storage tank 2 and the stirring body 110 to the steel in the storage tank 2 is radially formed on the bottom surface of the stirring body 110, As shown in Fig.

The present invention is capable of forcibly circulating the fluid introduced into the space 2a formed between the agitator 100 and the storage tank 2 provided at the upper end of the rotating shaft 40 passing through the coupling portion 10.

The second stirring vane 130 is radially protruded from the bottom surface of the agitator 100 so that the fluid introduced into the spaces 2a can be circulated forcibly

As shown in FIGS. 4 and 5, the second stirring vane 130 protruding from the bottom of the stirrer 100 is formed with a hemispherical curved surface 141 on one surface thereof,

And a wing body 140 having a guiding surface 142 inclined toward the outer side of the agitator 100 at the center of the other surface,

The lower portion of the wing body 140 is formed with an inclined surface 143 inclined upward from the inner end 140a to the outer end 140b.

At this time, it is revealed that the guide surface 142 is formed to be inclined in a direction in which the stirrer 100 is rotated.

The fluid introduced into the space 2a between the storage tank 2 and the agitator 100 is discharged to the outside through the second stirring blade 130 by the rotation of the motor 60. Therefore, The inflow fluid is strongly radiated to the outside along the guide surface 142 provided on the wing body 140 and the inclined surface 143 is strongly protruded from the guide surface 142, The outer end 140b is provided with the widened gap G2 as compared with the gap G1 formed at the inner end 140a of the wing body 140 so that a large amount of fluid can be forcedly circulated rapidly, The effect of reducing the time can be expected.

The preferred operating conditions and effects of the present invention will now be described.

First, the motor 60 installed inside the housing 1 is rotated by the On signal of the switch to rotate the drive pulley 62 in one direction.

The rotating force of the driving pulley 62 rotated by the operation of the motor 60 is transmitted to the connecting pulley 50 connected to the belt 70 and the rotating shaft 40 passed through the connecting pulley 50 is transmitted to the motor 60, And rotates the stirrer 100 installed in the rotary shaft 40 in the clockwise direction as shown in FIG.

The fluid stored in the storage tank 2 is forcibly circulated because the stirrer 100 rotates so that the first stir vane 120 and the second stir vane 130 are connected to the stirring body 110 ), The fluid flowing between the storage tank 2 and the space 2a is forcibly circulated at the same time.

2, the first stirring blade 120 protruding from the upper portion of the stirring body 110 forcibly circulates the fluid located in the upper portion of the stirrer 100, and the lower surface of the stirring body 110 is protruded The second stirring vane 130 formed is forcibly circulating the fluid introduced into the space 2a between the bottom surface of the storage tank 2 and the agitator 100.

Therefore, since the second stirring vane 130 forcibly circulates the fluid introduced into the space 2a, deposits of the fluid in the space 2a can be prevented from accumulating, It is possible to prevent the fluid that is being formed from being damaged due to the sediment.

5 (b), the wing body 140 of the second stirring vane 130 is formed with a hemispherical curved surface portion 141 on its one surface, and on the other surface of the wing body 140, And a curved surface 141 and an induction surface 142 are formed on the bottom surface of the wing body 140. The curved surface 141 and the induction surface 142 are formed on the bottom surface of the wing body 140, And an inclined surface 143 inclined upward toward the upper surface 140b.

The fluid introduced into the space 2a is forced to circulate through the second stirring blade 130 formed at the lower portion of the stirrer 100 when the stirrer 100 rotates, The wings 140 and the wing bodies 140 are gathered in the middle of the wing body 140 due to the guiding surfaces 142 inclined outward about the center of the wing bodies 140 and at the same time, So that a large amount of fluid can be forcedly circulated.

6, the inner end 140 of the wing body 140 has a gap G1 which is greater than the gap G1 of the inner end 140 of the wing body 140 (see FIG. 6) due to the inclined surface 143 provided on the bottom surface of the second stirring vane 130 G2 can form a widened space so that the fluid present in the space 2a can flow a large amount of fluid to the upper part of the storage tank 2 due to the expanded gap G2, The fluid can be forcedly circulated.

6, since the wing body 140 of the second stirring vane 130 forms the inclined surface 143 at the outer end higher than the inner end 140a, the inclined surface 143 prevents the inclined surface 143 A space of the outer gap G2 is enlarged between the wing body 140 and the wing body 140 and a large amount of fluid along the widened slant face 143 flows from the middle of the bottom surface of the stirrer 100 A large amount of fluid introduced into the space 2a can be forcibly circulated along the fluid circulating to the upper portion of the agitator 100. As a result, You can do it fast.

Therefore, it is possible to prevent the generation of sediments in the space 2a due to the second stirring vane 130, thereby preventing an overload from being generated in the motor 60 that rotates the rotation shaft 40.

7 and 8 show another embodiment of the second stirring vane 130 of the present invention. The same reference numerals are used for the same components, and the description of the same reference numerals will be omitted.

In another embodiment of the present invention,

And the second stirring blade 130 is further provided on the bottom surface of the agitator 100 so as to project and retract.

7 (a) and 7 (b), the protruding and detaching means 150 is provided with an opening end 161 on the bottom surface of the stirrer 100 and a first stopping end 162 is provided inside the opening end 161, This protruded groove 161 is formed,

A second engaging end 171 opposing the first engaging end 162 protrudes upward and a spring 172 is interposed between the first engaging end 162 and the second engaging end 171, The blade 130 is inserted into the groove 160,

A metal plate 173 is coupled to the inside of the second stirring vane 130,

An electromagnet 180 which is magnetized by a power source supplied every predetermined period and draws a second stirring vane 130 having a metal plate 173 from the groove 160 is installed on the bottom surface of the storage tank 2 .

That is, according to another embodiment of the present invention, the electromagnet 180 magnetized by a power source supplied at regular intervals is installed on the bottom surface of the storage tank 2, and the electromagnet 180 is moved from the bottom surface of the stirring body 110 by the magnetic force of the electromagnet 180 And the second stirring vane 130 is installed so as to be drawn out.

A groove 160 is radially formed on the bottom surface of the stirrer 100 so that the second stirring blade 130 is drawn out from the stirring body 110 and the wing body 170 of the second stirring blade 130 And is installed inside the groove 160 so as to be resilient to the spring 173.

Accordingly, when a magnetic force is generated from the electromagnet 180 magnetized by the power supply of the control period of the control device, the metal plate 173 coupled to the inside of the wing body 170 is rotated by the magnetized electromagnet 180 The second stirring vane 130 is moved in the direction of the electromagnet 180 due to the magnetic force of the electromagnet 180 to be drawn out from the groove 160 as shown in FIG.

The drawn second stirring vane 130 flows into the groove 160 which is the initial state due to the elastic force of the spring 172 because the power supplied from the electromagnet 180 is not magnetized at the same time as the power source is cut off.

Since the second agitating blade 130 is rotated in the direction in which the agitator 100 is rotated in the state where the second agitating blade 130 is drawn out from the groove 160, the fluid introduced into the space 2a between the storage tank 2 and the agitator 100 To be forced to circulate.

In particular, although not shown in the drawing, the electromagnet 180 installed at the lower portion of the storage tank 2 generates a magnetic force while the power is supplied for every predetermined period of the control device, and the second stirring vane 130 is taken out from the stirrer 100 Therefore, it is possible to prevent the motor 60 for rotating the stirrer 100 from being overloaded.

Also, since the second stirring vane 130 is drawn out from the agitator 100 due to the electromagnet magnetized at regular intervals to forcibly circulate the fluid introduced into the space 2a, the power consumption of the motor 60 can be reduced Effect can be expected.

And the electromagnet 180 installed in the lower part of the storage tank 2 is formed in a cylindrical shape like a donut shape.

1: housing, 2: storage tank,
2a: space, 3: refrigerant tube,
4: mounting hole, 10: engaging portion,
11: shaft hole, 12: body part,
30: bearing housing, 40: rotating shaft,
50: connection pulley, 60: motor,
70: belt, 80: stirrer,
81: stirring blade, 100: stirrer,
110: stirring body, 120: first stirring blade,
130: second stirring blade, 140: wing body,
140a: Inner end, 140b: Outer end,
141: curved portion, 142: guiding surface,
143: sloped surface, 150: protruding means,
160: home, 161: opening,
162: first stopping end, 170: wing body,
171: second stop, 172: spring,
173: metal plate, 180: electromagnet,

Claims (3)

Wherein the rotary shaft (40) rotated by receiving the rotational force of the motor (60) is installed to penetrate the bottom surface of the storage tank (2) and the stirrer (100) is installed on the rotary shaft (40) ,
The agitator (100)
A disk-shaped stirring body 110 is formed,
A first stirring blade 120 is radially protruded from an upper portion of the stirring body 110,
A second stirring blade 130 for circulating the fluid introduced into the space 2a between the storage tank 2 and the stirring body 110 to the steel in the storage tank 2 is radially formed on the bottom surface of the stirring body 110, Respectively,
The protruding and dismounting means 150 is further provided so that the second stirring vane 130 is projected and retracted on the bottom surface of the agitator 100,
The appearance / appearance means (150)
A groove 160 having an opening end 161 is formed radially on the bottom surface of the stirrer 100,
A second stirring blade 130 is installed on the inner side of the groove 160 and resiliently biased by a spring 172,
The spring 172 has a first stopping end 162 protruding from the opening end 161,
A second engaging end 171 opposed to the first engaging end 162 is formed on the upper end of the second stirring vane 130 so that the spring 172 is inserted between the first engaging end 162 and the second engaging end 171 The second stirring vane 130 can be maintained in a state in which the second stirring vane 130 flows into the groove 160 by the elastic force of the spring 172,
A metal plate 173 is coupled to the inside of the second stirring vane 130,
An electromagnet 180 which is magnetized by a power source supplied at regular intervals and draws a second stirring vane 130 having a metal plate 173 from the groove 160 is installed on the bottom surface of the storage tank 2 And the fluid agitating device.
The method according to claim 1, wherein the second stirring vane (130)
A hemispherical curved surface portion 141 is formed on one surface,
And a wing body 140 having a guiding surface 142 inclined toward the outer side of the agitator 100 at the center of the other surface,
Wherein a lower portion of the wing body (140) is formed with an inclined surface (143) inclined upward from an inner end (140a) to an outer end (140b).
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