KR102269592B1 - 3-Dimensional 3-way valve on syringe pump - Google Patents

Abstract

The present invention relates to a three-dimensional three-way valve on a syringe pump, which comprises: a valve housing which has a shaft insertion part configured therein, and includes an injection hole formed to communicate vertically from the shaft insertion part, and having a liquid supplied thereto, a discharge hole formed at a position opposite to the injection hole to discharge the liquid supplied from a syringe toward a dispensing needle, and a guide hole for guiding the liquid supplied from the injection hole to be injected into the syringe; and a valve shaft which includes a shaft body part rotatably inserted into the shaft insertion part, and a connecting shaft rotating the shaft body part in both directions or in one direction by a certain angle, and is configured to enable communication between the injection hole and the guide hole, or between the discharge hole and the guide hole, or between the injection hole and the discharge hole, according to the rotation amount of the shaft body part so that the liquid moves. The present invention can improve the dispensing precision of a chemical solution.

Description

3-Dimensional 3-way valve on syringe pump}

The present invention relates to a three-dimensional three-way valve of a syringe pump, and more particularly, by enabling the three-way valve mounted on the syringe pump to achieve miniaturization, directly connecting the syringe pump with a needle without a connecting hose, or a needle transfer module A three-dimensional 3D syringe pump that can improve the dispensing precision of the chemical solution by directly installing it on the device, thereby reducing the length of the connecting hose connecting the needle and the three-way valve to 1/3 or less than the length of the conventional connecting hose. It's about the room valve.

In general, a syringe pump is used to discharge and supply the contents of a liquid or powder contained in a syringe in a fixed amount by moving the plunger back and forth.

Such a syringe pump is widely applied throughout the industry, such as injection of raw materials in semiconductor and LCD processes, mixing of reagents in the pharmaceutical industry, and parts requiring quantitative input of other raw materials such as injection and material input in the food industry.

For example, in Korean Patent Laid-Open Publication No. 10-2017-0006174, a syringe 10 for discharging the liquid contained therein by a forward and backward movement of the plunger 12, and an injection hole 21 for injecting the liquid into the syringe 20 ) and the on/off valve 20 for selectively opening the discharge hole 22 for discharging the liquid of the syringe 20, and the power to convert the rotational motion of the stepping motor M1 into a linear motion to move the plunger 12 An ultra-precision syringe metering pump composed of the delivery unit 30 has been disclosed.

As shown in FIGS. 1 and 2, the opening/closing valve 20 of the prior art document has an injection hole 21 and a discharge hole 22 and a connection hole 23 connected to the syringe 10 at 120°. It is formed at intervals, and the motor shaft configured in the step motor is configured to rotate left and right so that the injection hole 21 and the connection hole 23, or the discharge hole 22 and the connection hole 23 are selectively communicated do.

However, according to the above-mentioned prior art document, when used as an automatic dispenser, the size of the on/off valve is inevitably formed large, so even if a syringe metering pump is mounted on the dispenser, there is a certain interval with the needle for supplying the chemical solution. It is inevitably installed in an open state, and the length of the hose connecting the syringe metering pump and the needle is inevitably extended, so there is a problem in that dispensing precision is lowered due to expansion and contraction of the hose over a long distance.

Here, the above-mentioned background or prior art is only for helping to understand the technical meaning of the present invention, and does not mean a technique widely known in the technical field to which the present invention pertains before the application of the present invention.

Republic of Korea Patent Publication No. 10-2017-0006174

In order to solve this problem, the present invention has been devised by the above-mentioned background art, and by enabling the three-way valve mounted on the syringe pump to achieve miniaturization, the syringe pump is connected to the needle without a connecting hose, or the needle transfer A three-dimensional three-way valve of a syringe pump that can improve the precision of dispensing chemicals by directly mounting on the module and reducing the length of the connecting hose connecting the needle and the three-way valve to 50% or less than the length of the conventional connecting hose. Its purpose is to provide

However, the object of the present invention is not limited thereto, and even if not explicitly mentioned, the object or effect that can be grasped from the solution or embodiment of the problem is also included therein.

According to an embodiment of the present invention for achieving the above object, the shaft insertion portion is configured, is formed to communicate vertically from the shaft insertion portion, the injection hole to which the liquid is supplied, and the injection hole at a position opposite to the injection hole a valve housing comprising: a discharge hole for discharging the liquid supplied from the syringe toward the dispensing needle; and a guide hole for guiding the liquid supplied from the injection hole to be injected into the syringe; A shaft body portion rotatably inserted into the shaft insertion portion, and a connecting shaft that rotates the shaft body portion in either direction or in one direction by a predetermined angle, depending on the amount of rotation of the shaft body portion, the injection hole and the guide hole, or and a valve shaft configured to communicate the discharge hole and the guide hole, or the injection hole and the discharge hole, so that the liquid moves.

According to an embodiment of the present invention, the valve housing minimizes the distance between the discharge hole and the dispensing needle, and prevents a change in the pressure of the discharged liquid from occurring to improve the dispensing precision of the liquid. characterized in that

According to an embodiment of the present invention, the discharge hole is configured to be spaced apart from the injection hole by a predetermined distance, and is configured to be located on the same line.

According to an embodiment of the present invention, the guide hole is formed on a coaxial line with the discharge hole.

According to an embodiment of the present invention, the shaft body portion has an injection-side connection hole for communicating the injection hole, and is configured in the form of a long groove on the outer circumferential side of the shaft body portion to communicate the injection-side connection hole and the guide hole. A first connection part composed of a first guide-side connection hole, a discharge-side connection hole that is formed to pass through the rear side of the shaft body part, and communicates with the discharge hole, and a second guide-side connection hole that communicates with the guide hole It is characterized in that it is composed of a second connection part to be formed, and a third connection part configured to form a long groove along the longitudinal direction of the shaft body part, and directly communicating the injection hole and the discharge hole.

According to an embodiment of the present invention, a communication portion formed inside the shaft body portion, the lower end of the injection hole and the discharge hole, and the upper end of the guide hole are configured to communicate with each other, and the communication portion and the injection hole communicate with each other. A first connection part consisting of an injection-side connection hole and a first guide-side connection hole for communicating the communication part and the guide hole, and a discharge-side connection communicating with the discharge hole, configured to be orthogonal from an axial center of the communication part A second connection part consisting of a hole and a second guide-side connection hole communicating with the guide hole, and configured to form a long groove along the longitudinal direction of the shaft body 210, the injection hole and the discharge hole directly communicate It is characterized in that it consists of a third connection part.

According to an embodiment of the present invention, the first connection part is characterized in that it is configured to form an inclination angle of 30 ° ~ 45 ° from the axis center of the shaft body part.

According to an embodiment of the present invention, only one of the first and second connection parts is configured to communicate with the communication part and the guide hole, respectively, when the shaft body part rotates.

According to an embodiment of the present invention, when the third connection part is connected to the injection hole and the discharge hole, both the first and second connection parts are configured to be sealed by the outer peripheral surface of the shaft body part. .

According to an embodiment of the present invention, the injection hole, the discharge hole, and the guide hole are formed in one direction in the valve housing to be parallel to the center of the axis of the valve shaft.

According to an embodiment of the present invention, the valve shaft has an upper connection part for communicating the injection hole and the guide hole to allow movement of the liquid, a side connection part for communicating the guide hole and the discharge hole, and the injection It is characterized in that it is composed of a lower connection part connecting the hole and the discharge hole.

According to an embodiment of the present invention, the upper connection part, the side connection part and the lower connection part are configured in the form of a long groove along the longitudinal direction of the shaft body part.

According to an embodiment of the present invention, the lower connection portion includes a first communication groove formed vertically from the shaft center of the shaft body portion so as to be located on the same axis as the shaft center of the injection hole during the rotation operation of the shaft body portion; A liquid moving groove connected to the lower end of the first communication groove to form a right angle and guiding the movement of the liquid flowing in from the first communication groove, and vertically connected to an end of the liquid moving groove, the first communication groove It is characterized in that it is formed in a shape corresponding to and is composed of a second communication groove communicating with the discharge hole.

According to this embodiment of the present invention, the three-way valve mounted on the syringe pump can be miniaturized, so that the syringe pump can be directly mounted on the needle transfer module, thereby connecting the needle and the three-way valve By reducing the length of the hose to 1/3 or less than the length of the conventional connecting hose, there is an effect of improving the dispensing precision of the chemical.

In addition, various and beneficial advantages and effects of the present invention are not limited to the above, and will be more easily understood in the course of describing specific embodiments of the present invention.

1 and 2 are schematic views of a syringe pump according to the prior art;
3 is an exploded perspective view showing a three-dimensional three-way valve of the syringe pump according to the first embodiment of the present invention;
4 is a cross-sectional view showing the valve shaft of the three-dimensional three-way valve of the syringe pump according to the first embodiment of the present invention;
5a to 5c are operational state diagrams showing the valve shaft of the three-dimensional three-way valve of the syringe pump according to the first embodiment of the present invention;
6 and 7 are perspective views showing the valve shaft of the three-dimensional three-way valve of the syringe pump according to the second embodiment of the present invention;
8 to 10 are combined cross-sectional views showing a three-dimensional three-way valve of a syringe pump according to a second embodiment of the present invention;
11 to 13 are views showing a three-dimensional three-way valve of a syringe pump according to a third embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are given the same reference numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, terms such as "include", "comprise" or "have" described below mean that the corresponding component may be embedded, unless otherwise stated, so that other components are excluded. Rather, it should be construed as being able to further include other components, and all terms including technical or scientific terms are generally used by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined. have the same meaning as understood. In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but another component is between each component. It should be understood that elements may be “connected,” “coupled,” or “connected.”

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

As shown, the three-dimensional three-way valve of the syringe pump of the present invention is configured to inject and discharge a liquid containing a medical liquid, and is connected to the valve housing 100 and the driving means mounted on the syringe pump, It is rotatably coupled to the valve housing 200 and controls the movement direction of the liquid while rotating by a predetermined angle, and includes a valve shaft 200 configured to enable precise liquid dispensing.

The valve housing 100 includes a coupling flange 102 coupled to the syringe pump at the rear end thereof, coupled to the front of the coupling flange 102, and a valve body 110 into which the valve shaft 200 is inserted. .

The valve body 110 is formed with a shaft insertion portion 112 that enables bidirectional rotation by a predetermined angle depending on whether the driving means is driven.

At this time, the coupling flange 102 is preferably formed through its central portion so that the valve shaft 200 can be inserted into the shaft insertion portion 112 of the valve body 110, but is not limited thereto, and the valve body 110 ) may be integrally configured with the rear end of the.

The shaft insertion part 112 is formed in the shape of a normal circular groove, and is configured to communicate with the injection hole 120 , the discharge hole 130 , and the guide hole 140 through which the liquid is injected and discharged.

Here, the injection hole 120 is formed on the upper surface of the front side of the valve housing 100 , is formed perpendicular to the center of the axis of the valve housing 100 , and is supplied with a liquid containing a medical liquid and injected into the syringe. This is configured so that it is connected to a component such as a liquid injection tank and a connecting hose.

The injection hole 120 injects the supplied liquid into the first connection part 220 only when the valve shaft 200 rotates and communicates with the first connection part 220 and the third connection part 240 to be described later. is configured to move.

At this time, the first connection part 220 has an injection-side connection hole 222 communicating with the injection hole 120 is formed, and the liquid injected through the injection-side connection hole 222 is moved to the guide hole 140 side. It is composed of a first guide-side connection hole 224 formed in the form of a long groove.

The discharge hole 130 is formed in the upper surface of the rear side of the valve housing 100, is configured to be spaced apart from the injection hole 120 by a predetermined distance, is configured to be positioned on the same line, and dispenses a predetermined amount of liquid discharged from the syringe. It is a component that guides so that it can be moved to the needle side.

The discharge hole 130 is formed vertically from the center of the axis of the valve housing 100, and is configured to be connected to the dispensing needle through a connection hose or the like.

That is, the injection hole 120 and the discharge hole 130 of the present invention are formed vertically from the center of the axis, and the size of the three-way valve configured in the syringe pump can be reduced, thereby minimizing the overall configuration of the syringe pump. As it becomes possible to implement, the configuration of the syringe pump itself is configured to be directly mounted on the needle transfer module provided with the dispensing needle.

In addition, since it is possible to minimize the distance between the discharge hole 130 and the dispenser needle, the length of the connecting hose connected to the discharge hole 130 can also be minimized, thereby preventing a change in the pressure of the discharged liquid from occurring. This can be done, and thus the liquid can be supplied to the dispensing needle side at a constant pressure, thereby improving the liquid dispensing precision.

The discharge hole 130 is configured to communicate with the first to third connection parts 220 , 230 , and 240 to be described later by rotation of the valve shaft 200 , respectively.

In addition, it is preferable that the injection hole 120 and the discharge hole 130 further include a hose connection part 150 to which a connection member such as a hose connector configured in the connection hose is detachably coupled.

On the other hand, the guide hole 140 is vertically penetrating the lower portion of the valve body 110 , and is configured to be connected to the first to third connection parts 220 , 230 , 240 of the valve shaft 200 , and the discharge hole Formed on the same axis as 130, the lower end is configured to be connected to the syringe to guide the liquid supplied from the injection hole 120 to be injected into the syringe, and the liquid discharged from the syringe is moved to the discharge hole 130 side It serves to guide you.

As shown in FIGS. 6 to 10 , the guide hole 140 of the present invention configured as described above is vertically penetrating the lower portion of the valve body 110 , and a second connection part 230 of the valve shaft 200 to be described later. ) to be configured to be connected to the communication part 212 through, it is formed on the same axis as the discharge hole 130, and the lower end is configured to be connected to the syringe, so that the liquid supplied from the injection hole 120 can be injected with a syringe. and guides the liquid discharged from the syringe to flow into the communication unit 212 , thereby guiding the introduced liquid to move toward the discharge hole 130 .

Although the guide hole 140 has been described as penetrating perpendicularly to the lower portion of the valve body 110 , the present invention is not limited thereto, and as shown in FIGS. 11 to 13 , injection according to the shape of the valve shaft 200 . It may be formed between the hole 120 and the discharge hole 130 .

A positioning pin 160 for setting the initial rotational position of the valve shaft 210 when the valve shaft 210 to be described later is first inserted into one side of the injection hole 120 is coupled to the valve body 110 of the present invention as described above. can be

At this time, the valve body 110 is further configured with a pin insertion hole 114 into which the positioning pin 160 is inserted, and the positioning pin 160 is inserted into the pin insertion hole 114 by press-fitting. may be configured, but is not limited thereto.

The valve shaft 200 includes a shaft body part 210 that is rotatably inserted into the shaft insertion part 112 configured in the valve body 110 , and the shaft body part 210 extending behind the shaft body part 210 and forming the valve shaft 200 . ) is composed of a connecting shaft 202 that is connected to a driving means such as a motor to enable bidirectional or unidirectional rotation by a certain angle.

As shown in FIGS. 3 to 5 , the shaft body 210 is configured to be in communication with the injection hole 120 , the discharge hole 130 , and the guide hole 140 , respectively, so that the liquid moves through the first to third connection parts 220 , 230 , and 240 are configured.

The first connection part 220 is configured in the form of a long groove on the side of the shaft body part 210 to connect the injection hole 120 and the guide hole 140 , and the first connection part 220 and the injection hole are penetrated by one end of the first connection part 220 . The injection-side connection hole 222 for communicating the hole 120 is formed so that the injection-side connection hole 222 communicates with the injection hole 120 when the shaft body 210 is rotated by the driving of the driving means. is supplied and introduced into the first guide-side connection hole 224 side of the long groove, and the liquid moved through the first guide-side connection hole 224 is supplied to the guide hole 140 side.

The second connection part 230 is formed to pass through the rear side of the shaft body part 210 , and is configured to be orthogonal to the shaft center of the shaft body part 210 , and a discharge side connection hole communicating with the discharge hole 130 . 232 and a second guide-side connection hole 234 communicating with the guide hole 140 .

Here, the discharge-side connection hole 232 and the second guide-side connection hole 234 are configured such that their axial centers are positioned on the same center line, and the discharge-side connection hole 232 is a pressure through which the liquid flowing from the syringe flows through the guide hole 140 . It flows into the discharge hole 130 side through the connection hole 232 and is configured to move toward the dispensing needle side through the connection hose.

The third connection part 240 is formed on the lower surface of the shaft body part 210 , and is configured to form a long groove along the longitudinal direction of the shaft body part 210 , and when the shaft body part 210 is rotated The injection hole 120 and the discharge hole 130 are configured to communicate directly, and the liquid supplied from the injection hole 120 is moved to the discharge hole 130 side to move toward the dispensing needle side through the connection hose. to be.

In addition, the first to third connection parts 220 , 230 , 240 have been described as being configured in the upper part, the side part, and the lower part of the shaft body part 210 based on FIGS. 3 to 5 , but the present invention is not limited thereto. It goes without saying that the positions for the upper, side and lower portions may be changed depending on the orientation or the initial insertion position.

In addition, the shaft body part 210 of the present invention is formed on the outer peripheral surface of the one side tip and when the insertion is made into the shaft insertion part 112 of the valve body 110, the initial position of the shaft body part 210 is set, and the valve An initial point determining panel 250 is further configured to serve as a stopper depending on whether the shaft 200 is in contact with the positioning pin 160 when the shaft 200 is rotated.

On the other hand, the shaft body portion 210 according to the second embodiment of the present invention is configured in the form of a circular groove therein, as shown in FIGS. 6 to 10 , and an injection hole 120 and a discharge hole 130 . A communication portion 212 configured to communicate with the lower end of the guide hole 140 and the upper end of the guide hole 140 may be formed.

The communication part 212 is configured so that the liquid supplied from the injection hole 120 can move to the guide hole 140 , and when the liquid discharged from the syringe is introduced through the guide hole 140 , the liquid is discharged through the discharge hole (130) serves to guide the movement to the side.

In addition, in the shaft body part 210 according to the second embodiment of the present invention, the first connection part 220 is formed as a through hole through which both front ends are respectively penetrated, and the rotational operation of the shaft body part 210 by driving the driving means. While communicating with the injection hole 120 , the liquid is supplied and introduced into the communication unit 212 side, and the liquid moved through the communication unit 212 is supplied to the guide hole 140 side.

As shown in FIG. 7 , the first connection part 220 is formed on the front side of the shaft body part 210, the upper end is selectively communicated with the injection hole 120, and the lower end is the communication part ( The injection-side connection hole 222 selectively communicates with the 212 and is formed in the lower rear side of the shaft body 210, the upper end is configured to communicate with the communication portion 212, and the lower end is the guide hole 140 ) and a first guide-side connection hole 224 configured to communicate.

At this time, the first connection part 220 is configured to be inclined by a certain angle from the axial center of the shaft body part 210 , and preferably, an inclination angle of 30° to 45° from the shaft center of the shaft body part 210 . is configured to achieve

In addition, the first connection part 220 is configured such that the injection-side connection hole 222 and the first guide-side connection hole 224 are located on the same center line. That is, the axial center of the injection-side connection hole 222 and the first guide-side connection hole 224 is configured to form the same inclination angle from the axial center of the shaft main body 210 .

As shown in FIG. 7 , the second connection part 230 is formed to pass through the rear side of the shaft body part 210 , and is configured to be orthogonal from the axis center of the communication part 212 , the discharge hole 130 . ) and a discharge-side connection hole 232 communicating with, and a second guide-side connection hole 234 communicating with the guide hole 140 .

Here, the discharge-side connection hole 232 and the second guide-side connection hole 234 are configured such that their axial centers are positioned on the same center line, and the discharge-side connection hole 232 is a pressure through which the liquid flowing from the syringe flows through the guide hole 140 . It flows into the discharge hole 130 side through the connection hole 232 and is configured to move toward the dispensing needle side through the connection hose.

However, the present invention is not limited thereto, and the liquid flowing in through the second guide-side connection hole 234 may be configured to flow out through the discharge-side connection hole 232 at a predetermined pressure while filling the communication part 212 . There will be.

As shown in FIG. 7 , the third connection part 240 is formed on the upper surface of the shaft body part 210 , from the upper front to the rear side of the shaft body part 210 , that is, the length of the shaft body part 210 . It is configured to form a long groove along the direction, and the injection hole 120 and the discharge hole 130 are configured to communicate directly when the shaft body 210 is rotated, and the liquid supplied from the injection hole 120 is It is a component that moves toward the discharge hole 130 and moves to the dispensing needle side through a connecting hose.

The third connection part 240 is configured to be parallel to the axial center of the communication part 212 , and is formed in a direction perpendicular to the axial center of the second connection part 230 .

In addition, the present invention is configured such that only one of the first and second connection parts 220 and 230 communicates with the communication part 212 and the guide hole 140 during the rotation operation of the shaft body part 210, respectively, and the shaft body When the third connection part 240 is connected to the injection hole 120 and the discharge hole 130 due to the rotational operation of the part 210 , the first and second connection parts 220 and 230 are both the shaft body part 210 . ) is configured to be sealed by the outer circumferential surface.

In addition, the first to third connection parts 220 , 230 , 240 have been described as being configured in the upper part, the side part, and the lower part of the shaft body part 210 based on FIGS. 6 to 10 , but the present invention is not limited thereto. It goes without saying that the positions for the upper, side and lower portions may be changed depending on the orientation or the initial insertion position.

Meanwhile, in the valve housing 100 of the present invention, as shown in FIGS. 11 to 13 , the injection hole 120 , the discharge hole 130 , and the guide hole 140 may be formed in one direction.

That is, the injection hole 120 , the discharge hole 130 , and the guide hole 140 are formed parallel to the axial center of the valve shaft 200 .

In addition, when the injection hole 120 , the discharge hole 130 , and the guide hole 140 are formed in one direction, the guide hole 140 is also connected to the syringe, such as a hose connector configured in a connection hose. It is preferable that the hose connection part 150 to which the member is detachably coupled is further configured.

At this time, as shown in FIGS. 11 to 13 , the valve shaft 200 includes an upper connection part 320 that communicates the injection hole 120 and the guide hole 140 so that the liquid moves, and a guide hole ( A side connection part 330 for communicating 140 with the discharge hole 130 and a lower connection part 340 for connecting the injection hole 120 and the discharge hole 130 may be configured.

At this time, the upper connection part 320, the side connection part 330 and the lower connection part 340 are formed in the shaft body part 210 of the valve shaft 200, and along the longitudinal direction of the shaft body part 210, the long groove made to take shape.

In addition, the lower connection part 340 is configured such that when the injection hole 120 and the discharge hole 130 are connected, the guide hole 140 is connected in a blocked state, and in the present invention, the shaft body part 210 . The upper end selectively communicates with the injection hole 120 by the rotation of the first communication groove formed vertically from the axial center of the shaft body portion 210 so as to be located on the coaxial line with the axial center of the injection hole (120) 342 and the liquid moving groove 346 connected to the lower end of the first communication groove 342 to form an orthogonal, and guide the liquid flowing in from the first communication groove 342 to move toward the discharge hole 130 . ) and a second communication groove 344 connected vertically to the end of the liquid moving groove 346 and formed in a shape corresponding to the first communication groove 342 to communicate with the discharge hole 130 . .

The upper connection part 320, the side connection part 330 and the lower connection part 340 configured as described above are formed at intervals of 90° from each other on the outer peripheral surface of the shaft body part 210, and each branching point on the circumferential surface of the shaft body part 210 When the rotation operation of the shaft body part 210 is made by the driving means, only one of the upper connection part 320, the side connection part 330, and the lower connection part 340 is the injection hole 120, the discharge The hole 130 and the guide hole 140 are configured to communicate with each other.

On the other hand, the injection hole 120, the discharge hole 130, and the guide hole 140 presented above are names in consideration of the functional characteristics of the hole, and are defined for the convenience of understanding the invention, and the three holes presented in the invention are It can be applied by changing the functions of the injection hole 120 , the discharge hole 130 , and the guide hole 140 .

That is, the injection hole 120 may perform the functions of the discharge hole 130 and the guide hole 140 , or the discharge hole 130 may perform the functions of the injection hole 120 or the guide hole 140 , The guide hole 140 may function as the injection hole 120 or the discharge hole 130 .

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: valve housing 102: mating flange
110: valve body 112: shaft insertion part
114: pin press-in hole 120: injection hole
130: discharge hole 140: guide hole
150: hose connection 160: positioning pin
200: valve shaft 202: connecting shaft
210: shaft body portion 212: communication portion
220: first connection 222: injection side connection hole
224: first guide side connection hole 230: second connection part
232: discharge side connection hole 234: second guide side connection hole
240: third connection part 250: initial point determining pin
320: upper connection portion 330: side connection portion
340: lower connection part 342: first communication groove
344: second communication groove 346: liquid transfer groove

Claims (9)

The shaft insertion part 112 is configured, is formed in communication with the shaft insertion part 112, the injection hole 120 to which the liquid is supplied, and the injection hole 120 are formed in a position opposite to the supply from the syringe a valve housing 100 having a discharge hole 130 for discharging the liquid to be used toward the dispensing needle, and a guide hole 140 for guiding the liquid supplied from the injection hole 120 to be injected into a syringe;
It consists of a shaft body part 210 that is rotatably inserted into the shaft insertion part 112, and a connecting shaft 202 that rotates the shaft body part 210 in both directions or one direction by a predetermined angle, and the shaft body The injection hole 120 and the guide hole 140, or the discharge hole 130 and the guide hole 140, or the injection hole 120 and the discharge hole 130 are separated according to the rotation amount of the part 210. and a valve shaft 200 configured to communicate and move the liquid.
The valve housing 100 is formed in one direction in the valve housing 100 such that the injection hole 120 , the discharge hole 130 , and the guide hole 140 are parallel to the axial center of the valve shaft 200 . 3D of a syringe pump, characterized in that it minimizes the distance between the discharge hole 130 and the dispensing needle, and improves the dispensing precision of the liquid by preventing a change in the pressure of the discharged liquid from occurring 3-way valve.
According to claim 1,
The discharge hole 130 is configured to be spaced apart from the injection hole 120 by a predetermined distance, and is configured to be located on the same line,
The guide hole (140) is a three-dimensional three-way valve of a syringe pump, characterized in that formed on the same axis as the discharge hole (130).
According to claim 1,
The shaft body part 210 has
The injection-side connection hole 222 for communicating the injection hole 120 and the injection-side connection hole 222 and the guide hole 140 are configured in the form of a long groove on the outer circumferential side of the shaft body 210 . A first connection part 220 consisting of a first guide-side connection hole 224 for communicating the
A discharge-side connection hole 232 that is formed to pass through the rear side of the shaft body 210 and communicates with the discharge hole 130 , and a second guide-side connection hole 234 that communicates with the guide hole 140 . ) and a second connection part 230 consisting of,
A third connection portion 240 configured to form a long groove along the longitudinal direction of the shaft body portion 210 and directly communicating the injection hole 120 and the discharge hole 130
A three-dimensional three-way valve of a syringe pump, characterized in that it consists of.
According to claim 1,
The shaft body part 210 has
a communication part 212 formed therein, the lower end of the injection hole 120 and the discharge hole 130, and the upper end of the guide hole 140 being in communication with each other;
An injection-side connection hole 222 for communicating the communication part 212 and the injection hole 120, and a first guide-side connection hole 224 for communicating the communication part 212 and the guide hole 140 and a first connection part 220 consisting of
a second connection part 230 configured to be perpendicular from the axial center of the communication part 212 and communicated with the discharge hole 130 and the guide hole 140;
A third connection portion 240 configured to form a long groove along the longitudinal direction of the shaft body portion 210 and directly communicating the injection hole 120 and the discharge hole 130
A three-dimensional three-way valve of a syringe pump, characterized in that it consists of.
5. The method of claim 4,
The first connection part 220,
A three-dimensional three-way valve of a syringe pump, characterized in that it is configured to form an inclination angle of 30° to 45° from the axial center of the shaft body portion 210.
5. The method of claim 4,
When the shaft body part 210 is rotated, only one of the first and second connection parts 220 and 230 is configured to communicate with the communication part 212 and the guide hole 140, respectively,
When the third connection part 240 is connected to the injection hole 120 and the discharge hole 130 , the first and second connection parts 220 and 230 are both on the outer peripheral surface of the shaft body part 210 . A three-dimensional three-way valve of a syringe pump, characterized in that it is configured to be closed by
delete According to claim 1,
The valve shaft 200 has
An upper connection part 320 for communicating the injection hole 120 and the guide hole 140 to allow movement of the liquid, and a side connection part 330 for communicating the guide hole 140 with the discharge hole 130 . ) and a lower connection part 340 connecting the injection hole 120 and the discharge hole 130,
The three-dimensional three-way valve of a syringe pump, characterized in that the upper connection part 320, the side connection part 330, and the lower connection part 340 are configured in the form of a long groove along the longitudinal direction of the shaft body part 210.
9. The method of claim 8,
The lower connection part 330 is
A first communication groove 342 formed vertically from the axial center of the shaft body 210 so as to be coaxial with the axial center of the injection hole 120 when the shaft body 210 is rotated;
A liquid movement groove 346 connected to the lower end of the first communication groove 342 to form an orthogonal to it and guiding the movement of the liquid flowing in from the first communication groove 342;
A second communication groove 344 vertically connected to the end of the liquid moving groove 346 and formed in a shape corresponding to the first communication groove 342 to communicate with the discharge hole 130 .
A three-dimensional three-way valve of a syringe pump, characterized in that it consists of.

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