KR101326199B1 - High speed dispensing pump - Google Patents

Abstract

The present invention relates to a high speed dispensing pump, and more particularly, to a high speed dispensing pump for supplying a viscous liquid and dispensing at high speed through a nozzle.
An object of the present invention is to provide a high speed dispensing pump capable of quickly and accurately dispensing viscous liquid in minute units.
High speed dispensing pump according to the present invention, by using a magnet for converting the rotational motion to a linear motion for the lifting operation of the nozzle lifting relative to the nozzle, it is possible to quickly and accurately dispense the viscous liquid of the minute unit There is.

Description

High Speed Dispensing Pumps {HIGH SPEED DISPENSING PUMP}

The present invention relates to a high speed dispensing pump, and more particularly, to a high speed dispensing pump for supplying a viscous liquid and dispensing at high speed through a nozzle.

In the semiconductor process, a dispensing pump is used to perform an underfill process in which a flip chip is mounted on a substrate and a viscous liquid such as silicon is dispensed and filled between the substrate and the flip chip. When the pump is mounted on the X-Y stage and the silicon is dispensed while moving the nozzle of the pump along the periphery of the chip, the silicon flows into the space between the chip and the substrate by capillary action.

Further, in the process of manufacturing the LED device, an LED device emitting white light is produced by dispensing a fluorescent solution prepared by mixing a fluorescent substance in a powder state with a liquid synthetic resin onto an LED chip. Thus, a dispensing pump is also used for the purpose of dispensing a fluorescent solution on an LED element.

In addition, biochips sometimes produce biochips by mixing materials such as DNA chips in sap or plasma and dispensing them through a pump.

As such, there is a need for a high speed dispensing pump capable of quickly and accurately dispensing viscous liquid in very small units.

An object of the present invention is to provide a high speed dispensing pump capable of dispensing a viscous liquid in minute units quickly and accurately.

A high speed dispensing pump according to the present invention for achieving the above object, the high speed dispensing pump for supplying a viscous liquid (viscous liquid) through the inlet through the outlet formed in the nozzle, the body portion; A valve housing having a nozzle in which the outlet is formed, a valve space formed to fill the viscous liquid between the inlet and the inlet and the outlet; A rotating disk rotatably installed in the body portion and a plurality of first rotating magnets arranged in the up and down direction with the same polarity and installed in the circumferential direction; Rotating means connected to the rotating disk to rotate the rotating disk; An elevating body disposed to face the rotating body of the rotating disk so as to be movable up and down, and disposed at positions corresponding to the first rotating magnet of the rotating disk, respectively, to provide repulsive force to the first rotating magnet. A lifting disc having a plurality of first lifting magnets arranged in the lifting direction and installed on the lifting body, and lifting up and down by interaction between the first rotating magnet and the first lifting magnet; And a valve rod having at least a portion received in the valve space of the valve housing, the valve rod being connected to the elevating disk to elevate with respect to the valve housing with the elevating disk.

High speed dispensing pump according to the present invention, by using a magnet for converting the rotational motion to a linear motion for the lifting operation of the nozzle lifting relative to the nozzle, it is possible to quickly and accurately dispense the viscous liquid of the minute unit There is.

1 is a perspective view of a high speed dispensing pump according to a first embodiment of the present invention.
FIG. 2 is an exploded perspective view of some components of the high speed dispensing pump shown in FIG. 1. FIG.
3 is a cross-sectional view taken along line III-III of the high speed dispensing pump shown in FIG. 1.
4 is an enlarged view of a portion of the high speed dispensing pump shown in FIG. 3.
5 is a perspective view for explaining a part of the high speed dispensing pump shown in FIG. 1.
6 is an exploded perspective view showing a part of the high speed dispensing pump according to the second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a high speed dispensing pump according to a first embodiment of the present invention, FIG. 2 is an exploded perspective view of some components of the high speed dispensing pump shown in FIG. 1, and FIG. 3 is a high speed shown in FIG. 1. It is sectional drawing III-III of a dispensing pump.

1 to 3, the high speed dispensing pump according to the first embodiment of the present invention includes a body 110, a valve housing 120, a valve rod 160, a rotating disk 140, and a lifting disk ( 150).

Body 110 is a structure for supporting and fixing the entire system, the valve housing 120, the rotating disk 140 and the lifting disk 150 is installed in the body 110, respectively. When the body part 110 is installed in the X-Y stage, the high-speed dispensing pump of the present invention can dispense the viscous liquid 103 while being transported in the horizontal direction by the transfer of the X-Y stage.

The valve housing 120 is installed in the body portion 110. The valve housing 120 has an inlet 121, an outlet 122, and a valve space 123. The valve housing 120 receives the viscous liquid 103 from the outside through the inlet 121. In this embodiment, the syringe 101 filled with the viscous liquid 103 is connected to the inlet 121 through the connecting pipe 102. The nozzle 125 has an outlet 122 formed as a path through which the viscous liquid 103 supplied through the inlet 121 is discharged to the outside. The valve space 123 is a space in which the viscous liquid is filled between the inlet 121 and the outlet 122. A valve seat 124 is formed at an upper end of the outlet 122 extending upward and downward, and the viscous liquid 103 is externally discharged through the outlet 122 while the needle 161 described later with respect to the valve seat 124 is elevated. Dispense with.

The rotating disk 140 includes a rotating body 131, a driven pulley 134, a plurality of first rotating magnets 132, and a second rotating magnet 133. In the present embodiment, a rotating disk 140 having four first rotating magnets 132 and a second rotating magnet 133 will be described as an example. The rotating body 131 is rotatably installed with respect to the body portion 110. Four first rotating magnets 132 are installed in the rotating body 131 at equal angular intervals along the circumferential direction around the rotating shaft of the rotating body 131. 2 and 5, the first rotating magnet 132 is formed in a cylindrical shape extending in the vertical direction, respectively, and the upper side is arranged such that the negative side of the negative (-) pole. In the first embodiment, the first rotating magnet 132 is press-fitted to the rotating body 131 made of non-magnetic aluminum. The second rotating magnet 133 is arranged to have a polarity opposite to the first rotating magnet 132, that is, the upper side of the second rotating magnet 132 so that the lower side thereof becomes a negative pole. It is installed on the rotating body 131. That is, in the rotating body 131, the first rotating magnet 132 and the second rotating magnet 133 are alternately installed at intervals of 45 degrees along the circumferential direction.

The rotating disk 140 rotates with respect to the body portion 110 by the rotating means 140. The rotating means 140 comprises a motor 141, a drive pulley 142 and a belt 143. The motor 141 is fixed to the body portion 110 and the driving pulley 142 is connected to the motor 141 to rotate. The belt 143 connects the driving pulley 142 and the driven pulley 134 of the rotating disk 140. When the motor 141 rotates the drive pulley 142, the belt 143 connected to the drive pulley 142 rotates the driven pulley 134.

The elevating disk 150 is installed to the elevating body 110. The lifting disk 150 includes a lifting body 151, a plurality of first lifting magnets 152, and a plurality of second lifting magnets 153. The lifting body 151 is disposed to face the rotating body 131 of the rotating disk 140. In the present embodiment, four first lifting magnets 152 and second lifting magnets 153, which are the same number as the first rotating magnets 132 and the second rotating magnets 133, are installed in the lifting body 151. do. The first elevating magnet 152 is disposed on the elevating body 151 so as to correspond to the first rotating magnet 132 of the rotating disk 140, respectively. That is, the first lifting magnets 152 are press-fitted to the lifting body 151 at intervals of 90 degrees along the circumferential direction. The first lifting magnet 152 is arranged in a polarity in the direction to provide a repulsive force with respect to the first rotating magnet 132. That is, referring to FIGS. 2 and 5, the first elevating magnet 152 is installed on the elevating body 151 such that an upper side thereof becomes a positive (+) pole and a lower side thereof becomes a negative (−) pole. Accordingly, when the first rotating magnet 132 of the rotating disk 140 and the first lifting magnet 152 of the lifting disk 150 face each other, the first rotating magnet 132 and the first lifting magnet 152 respectively. ) Push the lifting disk 150 relative to the body portion 110 while pushing each other. The second lifting magnets 153 are respectively disposed between the first lifting magnets 152 and installed on the lifting body 151, and the second lifting magnets 153 are opposite in polarity to the first lifting magnets 152. Is arranged to have. That is, the second lifting magnet 153 is arranged so that the upper side becomes the cathode and the lower side becomes the anode. The first lifting magnet 152 and the second lifting magnet 153 are alternately arranged along the circumferential direction at 45 degree intervals. When the first rotating magnet 132 and the first lifting magnet 152 respectively face each other, the second rotating magnet 133 and the second lifting magnet 153 also face each other and generate a repulsive force to raise and lower the disk 150. ) Is raised relative to the body portion (110). When the rotating disk 140 rotates 45 degrees, the first rotating magnet 132 and the second lifting magnet 153 face each other and the second rotating magnet 133 and the first lifting magnet 152 face each other, An attractive force acts between the opposing magnets to lower the elevating disk 150 relative to the body 110.

The valve rod 160 is connected to the elevating disk 150. When the elevating disk 150 elevates with respect to the body portion 110, the valve rod 160 also elevates with the elevating disk 150. The valve rod 160 has a needle 161 and the needle 161 is received in the valve space 123 of the valve housing 120. Referring to FIG. 4, when the valve rod 160 is elevated, the needle 161 opens and closes the outlet 122 while elevating the valve seat 124 of the valve housing 120.

2 and 3, a spring 170 is installed between the body 110 and the valve rod 160. The spring 170 urges the valve rod 160 against the valve housing 120. That is, when the first rod magnet 132 and the first elevating magnet 152 face each other and the valve rod 160 with the elevating disk 150 is raised, the spring 170 is compressed, the first rotating magnet ( 132 and the second elevating magnet 153 face each other and when the valve rod 160 with the elevating disk 150 is lowered, the spring 170 pressurizes the valve rod 160 more quickly the valve rod 160 Help to fall.

On the other hand, in this embodiment, the rotating body 131 and the lifting body 151 is made of a nonmagnetic material, such as aluminum or ceramic, respectively. The first rotating magnet 132 and the second rotating magnet 133 are press-fitted to the rotating body 131, respectively, and the first lifting magnet 152 and the second lifting magnet 153 are also the lifting body 151, respectively. It is press-fitted into and installed.

Hereinafter, the operation of the high speed dispensing pump according to the first embodiment of the present invention configured as described above will be described.

The motor 141 of the rotating means 140 is operated in the state where the viscous liquid 103 stored in the syringe 101 is filled in the valve space 123 through the inlet 121. When the driving pulley 142 rotates, the rotating disk 140 rotates while the driven pulley 134 interlocked by the belt 143 rotates.

When the first rotating magnet 132 and the first lifting magnet 152 face each other and the second rotating magnet 133 and the second lifting magnet 153 face each other, the lifting disks are driven by the forces pushed against each other. 150 rises. The outlet 122 is opened while the needle 161 of the valve rod 160 raised together with the elevating disk 150 is raised.

When the rotating disk 140 rotates 45 degrees again, the first rotating magnet 132 and the second lifting magnet 153 face each other, and the second rotating magnet 133 and the first lifting magnet 152 face each other, causing the magnet to rotate. The elevating disk 150 is lowered by pulling each other. At this time, the valve rod 160 is also lowered along with the elevating disk 150. At this time, the spring 170 helps the valve rod 160 to descend more quickly. When the needle rod 161 approaches the outlet 122 as the valve rod 160 descends, the volume of the valve space 123 decreases to discharge the viscous liquid 103 in the valve space 123 to the outlet 122. do. In the viscous liquid 103 discharged by the needle 161, the discharge is stopped by closing the outlet 122 as the needle 161 strikes the valve seat 124.

When the rotating disk 140 rotates continuously, the lifting disk 150 repeatedly moves up and down by the action of the magnet as described above, and the viscous liquid 103 in the valve space 123 is externally discharged through the outlet 122. Discharged.

The high speed dispensing pump of this embodiment, which is constructed and operated as described above, repeatedly moves the elevating disk 150 while the rotating disk 140 and the elevating disk 150 are not in physical contact with each other by the action of a magnet. It can be elevated relative to the rotating disk 140. Therefore, there is an advantage that the rotating disk 140 can be easily rotated at a high speed, thereby dispensing the viscous liquid 103 at a high speed. In addition, since the elevating disk 150 can be elevated without bringing the rotating disk 140 and the elevating disk 150 into contact with each other, wear or damage of the rotating disk 140 and the elevating disk 150 can be prevented. There is an advantage.

In addition, the first rotating magnet 132 and the second rotating magnet 133 and the first lifting magnet 152 and the second lifting magnet 153 which are arranged in the circumferential direction on the rotating body 131 and the lifting body 151. By changing the number or the angular spacing) there is an advantage that the lifting frequency of the valve rod 160 can be easily adjusted.

As mentioned above, although the 1st Embodiment of the high speed dispensing pump which concerns on this invention was described, the scope of the present invention is not limited to the form demonstrated above and shown.

For example, while the first lifting magnet 152 and the second lifting magnet 153 are described as being arranged along the circumferential direction at intervals of 45 degrees, the number and the angular interval of the first lifting magnet and the second lifting magnet are It may be variously modified as necessary. The same applies to the number and arrangement of the first and second rotating magnets.

In addition, the first lifting magnet 152 and the second lifting magnet 153 is installed on the lifting body 151 from the front, and the first rotating magnet 132 and the second rotating magnet 133 are installed on the rotating body 131. Although described as being, the combination of the magnet installed on the lifting body and the rotating body can be variously modified. For example, only the first lifting magnet may be installed on the lifting body and only the first rotating magnet may be installed on the rotating body. In this case, when the first elevating magnet and the first rotating magnet face each other, the elevating disk is raised, and when the first elevating magnet and the first rotating magnet are crossed with each other, the elevating disk is lowered. In addition, the rotating body may be configured such that the first rotating magnet and the second rotating magnet are installed, and only the first lifting magnet is installed on the lifting body. In this case, when the first rotating magnet and the first lifting magnet face each other, the lifting disc rises, and when the first rotating magnet and the second rotating magnet face each other, the lifting disc lowers. On the contrary, only the first rotating magnet may be installed on the rotating body, and the first lifting magnet and the second lifting magnet may be installed on the lifting body. In this case, when the first rotating magnet and the first lifting magnet face each other, the lifting disc rises, and when the first rotating magnet and the second lifting magnet face each other, the lifting disc descends.

Meanwhile, in the first embodiment, the high speed dispensing pump has a structure in which the elevating disk 150 is disposed above the rotating disk 140, but the elevating disk 150 is disposed below the rotating disk 140. It is also possible.

In addition, in the high speed dispensing pump of the first embodiment shown in FIGS. 1 to 3, the valve rod 160 is configured to extend through the rotation center axis of the rotation disk 140, but the valve rod is extended from the rotation center of the rotation disk. It is also possible to arrange the arrangement so as to extend up and down in the off position.

Next, a second embodiment of the high speed dispensing pump according to the present invention will be described with reference to FIG. 6. 6 is an exploded perspective view showing a part of the high speed dispensing pump according to the second embodiment of the present invention. The high speed dispensing pump of the second embodiment is the same as the high speed dispensing pump of the first embodiment shown in FIGS. 1 and 2 except for the structures of the elevating disk 250 and the rotating disk 240.

The rotating disk 240 of the second embodiment is coupled to the rotary ring 234 on the outer periphery of the rotating body 231 of a nonmagnetic material. The rotary ring 234 is alternately connected to the first rotating magnet 232 and the second rotating magnet 233 is formed in a ring shape. The elevating disk 250 is also coupled to a lifting length on the outer circumference of the non-magnetic lifting body 251, and the lifting ring 254 is alternately connected to the first lifting magnet 252 and the second lifting magnet 253 to form a ring. Is formed. An upper side of the first rotating magnet 232 is a cathode and a lower side of the first elevating magnet 252 so that a repulsive force is generated at a position where the first rotating magnet 232 and the first rotating magnet 232 face each other. The upper side of the cathode is the anode. On the contrary, the upper side of the second rotating magnet 233 is a cathode below the anode, and the upper side of the second lifting magnet 253 is an anode below.

In addition to the configuration as described above, the structure of the lifting disk and the rotating disk can be variously modified.

110: body 120: valve body
130: rotating disk 140: rotating means
150, 250: elevating disc 160, 260: valve rod
131 and 231: rotating body 132 and 232: first rotating magnet
133, 233: second rotating magnet 134, 234: driven pulley
151, 251: lifting body 152, 252: first lifting magnet
153, 253: second lifting magnet

Claims (11)

A high speed dispensing pump for supplying viscous liquid through an inlet and dispensing through an outlet formed in a nozzle,
A body portion;
A valve housing having a nozzle in which the outlet is formed, a valve space formed to fill the viscous liquid between the inlet and the inlet and the outlet;
A rotating disk rotatably installed in the body portion and a plurality of first rotating magnets arranged in the up and down direction with the same polarity and installed in the circumferential direction;
Rotating means connected to the rotating disk to rotate the rotating disk;
An elevating body disposed to face the rotating body of the rotating disk so as to be movable up and down, and disposed at positions corresponding to the first rotating magnet of the rotating disk, respectively, to provide repulsive force to the first rotating magnet. A lifting disc having a plurality of first lifting magnets arranged in the lifting direction and installed on the lifting body, and lifting up and down by interaction between the first rotating magnet and the first lifting magnet; And
A valve rod having a needle received in at least a portion of the valve space of the valve housing, the valve rod being connected to the elevating disk to elevate with respect to the valve housing with the elevating disk;
The rotating disk further includes a plurality of second rotating magnets arranged to have polarities opposite to the first rotating magnets and installed on the rotating bodies between the first rotating magnets,
The elevating disk further comprises a plurality of second elevating magnets arranged in the elevating body between the first elevating magnets and arranged to have polarities opposite to the first elevating magnet. Dispensing Pump. delete delete delete The method of claim 1,
The rotating disk further comprises a driven pulley,
The rotating means,
A high speed dispensing pump, comprising: a motor, a drive pulley connected to the motor, and a belt connecting the drive pulley and the driven pulley of the rotating disk. The method of claim 1,
And a first elevating magnet and a second elevating magnet of the elevating disk are arranged at equal angular intervals with respect to the center of rotation of the elevating body along the circumferential direction. The method of claim 1,
And the first rotating magnet and the second rotating magnet of the rotating disk are arranged at equal angular intervals with respect to the center of rotation of the rotating body along the circumferential direction. The method of claim 1,
The first elevating magnet and the second elevating magnet of the elevating disk are arranged at equal angular intervals with respect to the center of rotation of the elevating body along the circumferential direction,
And the first rotating magnet and the second rotating magnet of the rotating disk are arranged at equal angular intervals with respect to the center of rotation of the rotating body along the circumferential direction. The method of claim 1,
And a spring installed between the body portion and the valve rod to press the valve rod against the valve housing. The method of claim 1,
The rotating body of the rotating disk is made of a nonmagnetic material, the first rotating magnet and the second rotating magnet is pressed into the rotating body is fixed,
The elevating body of the elevating disk is made of a nonmagnetic material, the first elevating magnet and the second rotating magnet is a high-speed dispensing pump, characterized in that the pressing body is fixed to the elevating body. The method of claim 1,
The rotating disk is formed by coupling a rotating ring formed by connecting the first rotating magnet and the second rotating magnet to the outer circumference of the non-magnetic material.
The elevating disk is a high speed dispensing pump, characterized in that the elevating ring formed by coupling the first elevating magnet and the second elevating magnet to the outer periphery of the elevating body of the non-magnetic material.

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