JP2000317369A - Quantitative discharge device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a quantitative discharge device which prevents the leakage of a liquid material and makes the quantity of liquid drops as small as possible at the stop of discharging the liquid material. SOLUTION: In this quantitative discharge device, where a driving part 24 drives a rod 22 so that a liquid passage toward a needle shaped-pipe 18 may be closed by travelling an end 22a of the rod 22 inserted movably in a syringe 12 to the direction of a discharge nozzle 18, the rod 22 is inserted in the syringe 12 so that the end 22a can be travelled into a cylindrical contacting part 20, and also a seal material 44 made of a resin, which is deformed by hitting an inside bottom surface of the cylindrical contacting part 20, is inserted in the cylindrical contacting part 20, and a liquid passage 46 of a diameter smaller than the outer diameter of the end 22a of the rod 22 is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a constant-rate discharge device, and more particularly, to a discharge nozzle of a syringe in which a liquid material to be discharged is stored, and a needle-like pipe having a smaller diameter than the discharge nozzle, which is formed by a cylindrical connection. When a predetermined amount of the liquid material connected and stored in the syringe is discharged,
To stop the discharge of the liquid material stored in the syringe from the needle-shaped pipe, one end of a rod movably inserted into the syringe is moved in the direction of the discharge nozzle,
The present invention relates to a fixed-rate discharge device provided with a drive unit that drives the rod so as to close a liquid passage to the needle pipe.

[0002]

2. Description of the Related Art A metering device shown in FIG. 6 is used as a metering device for injecting a predetermined amount of a liquid material such as oil into a bearing portion of a timepiece. 6, a syringe 102 made of a resin such as polypropylene in which a liquid material 100 such as oil is stored is accommodated in a cylinder 104 made of aluminum. Further, this syringe 102
A cylindrical connecting portion 110 to which a needle-shaped pipe 108 is fixed is attached to the discharge nozzle 106 formed at one end of the nozzle, and connects the discharge nozzle 106 and the needle-shaped pipe 108.
One end of the syringe 102 is provided in the syringe 102.
A stainless steel rod 112 is inserted so as to be movable along the long axis direction. This rod 112
Is formed in a thick portion 112a having a larger diameter than its main body, and the other end of the rod 112 is provided with a syringe 1
02 of the liquid material 100 stored inside
When stopping the discharge from the
a in the direction of the discharge nozzle 106, and
A drive unit 114 that drives the rod 112 is provided so as to close an inlet (hereinafter, simply referred to as an inlet) of the syringe 6 on the side of the syringe 102.

The driving unit 114 has a piston 118 at the other end of a rod 116 in which the other end of the rod 112 is inserted at one end. It is driven by compressed air supplied from compressed air nozzles 122 and 124 formed on the wall surface. As described above, the member 128 forming the inner wall surface of the piston driving chamber 126 driven by the piston 118 and having the rod 116 inserted therein is provided with the passage 13 communicating with the syringe 102.
The liquid material 100 stored in the syringe 102 by supplying a pressurized gas such as pressurized air as needed.
Can be pressurized. In addition, the stopper 1 for regulating the upper limit position of the piston 118 is provided in the constant-rate discharging device shown in FIG.
32 is provided, and the end face position of the stopper 132 can be adjusted by screws.

[0004]

In the fixed-rate discharge device shown in FIG. 6, after inserting the tip of the needle-shaped pipe 108 into a desired position, compressed air is supplied from the compressed air nozzle 124 to the piston driving chamber 1.
The liquid material 100 is discharged from the needle pipe 108 by moving the rod 112 in a direction in which the thick portion 112a of the rod 112 is separated from the inlet of the discharge nozzle 106.
At this time, a pressurized gas such as compressed air is supplied to the passage 130 as needed to pressurize the liquid material 100 in the syringe 102. Next, after a predetermined time elapses (after a predetermined amount of the liquid material 100 is discharged) by a timer or the like, the needle pipe 108
By continuously supplying compressed air from the compressed air nozzle 122 to stop the discharge of the liquid material 100 from the
2 is moved in the direction of the discharge nozzle 106 to keep the entrance of the discharge nozzle 106 closed by the thick portion 112 a of the rod 112. In this way, a predetermined amount of liquid material can be filled in a desired location.

However, when filling a low-viscosity liquid material using the constant-rate discharge device shown in FIG.
Even when the inlet of the discharge nozzle 106 is closed by 12a, liquid leakage may occur. In particular, when the filling location is filled with the liquid material by reducing the pressure, liquid leakage is likely to occur. When the liquid material is filled by decompressing the filling portion, even if the discharge nozzle 106 is completely closed by the thick portion 112a of the rod 112 and no liquid leakage occurs, the cylindrical shape due to the liquid dripping phenomenon occurs. The amount of the liquid material 100 flowing out of the pipe 108 is increased as compared with the case where the liquid material 100 is filled under the atmospheric pressure, and the variation in the discharge amount is increased. In such a fixed-volume discharge device in which the liquid leakage or dripping phenomenon occurs, a low-viscosity liquid material such as oil is filled in a bearing of a precision device such as a timepiece which is required to minimize variations in the liquid material. It cannot be used as a filling device.
Therefore, an object of the present invention is to reliably stop the discharge of the liquid material and to discharge the liquid material even when filling the low-viscosity liquid material by inserting the tip of a needle-shaped pipe into the filling point in a reduced pressure state. It is an object of the present invention to provide a constant-volume discharge device capable of minimizing a dripping phenomenon when stopping the operation.

[0006]

The present inventors have studied to solve the above-mentioned problems, and as a result, a sealing material made of a resin such as a fluororesin, which is deformed by contacting one end of the rod, is brought into contact with one end of the rod. Position, and by forming a liquid passage to the needle-shaped pipe having an inner diameter smaller than the outer diameter of one end of the rod in this seal material, when one end of the rod comes into contact with the seal material, The liquid passage of the sealing material is closed, and at the same time, the sealing material can be deformed by the pressing force of one end of the rod to complete the seal between one end of the rod and the sealing material. The present invention has been found that the dripping amount can be made as small as possible by forming the inside of the inside or the inside of the cylindrical connecting portion.

That is, according to the present invention, a discharge nozzle of a syringe in which a liquid material to be discharged is stored is connected to a needle-shaped pipe having a smaller diameter than the discharge nozzle by a cylindrical connecting portion, and is stored in the syringe. When a predetermined amount of the discharged liquid material is discharged, one end of a rod movably inserted into the syringe is connected to the discharge nozzle so as to stop discharging the liquid material stored in the syringe from the needle pipe. In a fixed-quantity discharge device provided with a drive unit that drives the rod so as to move in the direction of the arrow and close the liquid passage to the needle-shaped pipe, the rod has one end inside the discharge nozzle or the cylinder. One end of the rod is inserted into the syringe so as to be movable into the cylindrical connection part, and is positioned at a position where one end of the rod in the discharge nozzle or the cylindrical connection part can abut. A seal member made of a resin such as a fluororesin that is deformed by contact is provided, and the liquid passage having a diameter smaller than an outer diameter of one end of the rod is formed at a position where the seal member is in contact with one end of the rod. A fixed-quantity discharge device characterized in that:

The present invention also provides a syringe for storing a liquid material to be discharged, and a needle-shaped pipe having a smaller diameter than the discharge nozzle, which is connected by a cylindrical connecting portion, and is stored in the syringe. When a predetermined amount of the discharged liquid material is discharged, one end of a rod movably inserted into the syringe is connected to the discharge nozzle so as to stop discharging the liquid material stored in the syringe from the needle pipe. In the fixed-quantity discharge device provided with a driving unit for driving the rod so as to move in the direction of and close the liquid passage to the needle-shaped pipe, the end of one end of the rod has the cylindrical coupling unit. A sealing material such as a fluororesin which is deformed by contacting the inner wall surface of the rod is provided, and a liquid passage to the needle-like pipe is provided on the inner wall surface of the cylindrical connecting portion where the sealing material formed on the end surface of the rod abuts. Formation And the rod is inserted into the syringe such that the sealing material contacts the inner wall surface of the cylindrical connecting portion and the liquid passage is closed. .

In the quantitative discharge device shown in FIG.
When stopping the discharge of 00, the thick portion 112 of the rod 112
If a can completely close the discharge nozzle 106 in close contact with the inner wall surface of the syringe 102 forming the vicinity of the entrance of the discharge nozzle 106 over the entire circumference, the liquid material 100 can be prevented from leaking. However, the syringe 102 constituting the fixed-rate discharge device shown in FIG. 6 is formed of a rigid resin because the pressure of a pressurized fluid or the like is applied inside. Therefore, even if the thick portion 112a of the rod 112 abuts on the inner wall surface of the syringe 102 forming the vicinity of the inlet of the discharge nozzle 106, the inner wall surface does not substantially deform, and the thick portion 112a of the rod 112 and the syringe 112 A minute gap is easily formed between the inner wall surface and the inner wall surface. When the high-viscosity liquid material 100 is discharged in a constant amount under the atmospheric pressure, the liquid material 100 cannot easily pass through the fine gap and cannot leak out, but has a low-viscosity liquid that can pass through the fine gap. When the material 100 is discharged in a fixed amount, leakage occurs. In particular, when the tip of the needle-shaped pipe 108 is inserted into the filling place in a decompressed state and the low-viscosity liquid material 100 is discharged in a fixed amount, the liquid material 100 easily forms a fine gap due to the pressure difference between the syringe 102 and the filling place. The liquid material 100 can pass through and leak easily.

When the discharge of the liquid material 100 is stopped by closing the entrance of the discharge nozzle 106 by the thick portion 112a of the rod 112, the discharge nozzle 106 and the cylindrical connecting portion 11
0, and the liquid material 100 accumulates in the needle pipe 108. When the liquid material 100 has a high viscosity and the point where the tip of the needle-shaped pipe 108 is inserted is at atmospheric pressure, the liquid material 100 does not substantially flow out of the needle-shaped pipe 108, but when the liquid material 100 has a low viscosity, the needle-shaped The phenomenon of dripping out of the pipe 108 occurs. In particular, when filling the low-viscosity liquid material 100 by inserting the distal end of the needle-shaped pipe 108 into the filling point in a decompressed state, most of the liquid material 100 accumulated in the discharge nozzle 106 and the like drip from the needle-shaped pipe 108. Outflow by phenomenon. For this reason, the discharge amount varies due to the dripping phenomenon.

[0011] In this regard, in the quantitative discharge device according to the present invention,
The rod is inserted into the syringe such that one end of the rod can be moved into the discharge nozzle or the cylindrical connection part, and the rod is positioned at a position where one end of the rod in the discharge nozzle or the cylindrical connection part can abut. A seal member made of a resin that is deformed by contact with one end of the rod is provided, and a liquid passage having a smaller diameter than the outer diameter of one end of the rod is formed at a position where the seal member contacts one end of the rod. Therefore, when one end of the rod comes into contact with the sealing material, the liquid passage is closed by the rod, and at the same time, the sealing material is deformed by the pressing force of the rod to completely seal between the one end of the rod and the sealing material. As a result, liquid leakage can be prevented. In addition, since the sealing material is formed in the discharge nozzle or the cylindrical connecting portion, when the liquid passage is closed by one end of the rod, the amount of the liquid material stored in the discharge nozzle or the like is reduced as much as possible. Thus, the amount of liquid material flowing out due to the dripping phenomenon can be reduced as much as possible.

Further, in the metering device according to the present invention, a seal material which is deformed by contacting the inner wall surface of the cylindrical connecting portion is formed on one end face of the rod, and the seal material formed on the end face of the rod is provided. A liquid passage to the needle-shaped pipe is formed on the inner wall surface of the cylindrical connecting portion with which the sealing member abuts, and the liquid passage to the needle-shaped pipe is closed by the sealing material coming into contact with the inner wall surface of the cylindrical connecting portion. Next, the rod is inserted into the syringe. For this reason, the liquid passage to the needle-shaped pipe can be closed by the sealing material formed on the end face of one end of the rod, and at the same time,
As a result, the sealing between the sealing member and the liquid passage can be completed, so that liquid leakage can be prevented. In addition, since the sealing material formed on the end surface of the rod closes the liquid passage formed in the cylindrical connecting portion, when the liquid passage is closed by the sealing material, the amount of liquid material stored in the cylindrical connecting portion and the like can be reduced. The amount of liquid material flowing out due to the dripping phenomenon can be reduced as much as possible.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an example of a constant-rate discharge device according to the present invention. 1 includes a syringe 12 made of a resin such as polypropylene in which a liquid material 10 such as oil is stored, is housed in an aluminum cylindrical body 14, and is provided at one end of the syringe 12. The discharge nozzle 16 has a cylindrical connecting portion 2 to which a needle pipe 18 is fixed.
0 is attached. A stainless steel rod 22 is inserted into the syringe 12 so that one end thereof can move along the long axis direction of the syringe 12. One end of the rod 22 is formed in a detail 22 a having a smaller diameter than its main body, and is inserted into the cylindrical connecting portion 20 through the discharge nozzle 16. The other end of the rod 22 is moved so that the rod 22 moves in the direction of the discharge nozzle 16 when the discharge of the liquid material 10 stored in the syringe 12 from the needle pipe 18 is stopped. Is provided.

The drive unit 24 has a rod 22 at one end.
The other end of the rod 26 into which the other end of the
8 is provided, and the piston 28 is provided with compressed air nozzles 32 and 34 formed on the wall surface of the cylinder 30 into which the piston 28 is inserted.
Driven by compressed air supplied from the As described above, the member 38 forming the inner wall surface of the piston driving chamber 36 driven by the piston 28 and having the rod 26 inserted therein is provided with the passage 40 communicating with the syringe 12, and is provided with a compressed air or the like as necessary. The liquid material 10 stored in the syringe 12 can be pressurized by supplying a pressurized gas. In addition, the metering device shown in FIG. 1 is provided with a stopper 42 for regulating the upper limit position of the piston 28.
Can be adjusted by screws.

In the metering device shown in FIG. 1, a sealing member 44 made of a deformable resin such as fluororesin is inserted into the inner bottom surface of the cylindrical connecting portion 20. A liquid passage 46 to the pipe 18 is formed. The inner diameter of the liquid passage 46 is smaller than the detail 22a of the rod 22, as shown in FIG. When filling a desired portion with a liquid material using such a fixed amount discharge device shown in FIG. 1, after inserting the tip of the needle-like pipe 18 into the desired portion, the compressed air is discharged from the compressed air nozzle 34 into the piston. The liquid material 10 is supplied to the driving chamber 36, and the liquid material 10 is discharged from the needle pipe 18 by moving the rod 22 in a direction in which the details 22 a of the rod 22 are separated from the liquid passage 46 of the sealing material 44. At this time, a pressurized gas such as compressed air is supplied to the passage 40 as needed to pressurize the liquid material 10 in the syringe 12. Next, after a predetermined time elapses (after a predetermined amount of the liquid material 10 is discharged) by a timer or the like, the needle pipe 18
To stop the discharge of the liquid material 10 from the
The compressed air is supplied from 2 and the details 22 a of the rod 22 pass through the discharge nozzle 16 to close the liquid passage 46 of the sealing material 44 formed on the inner bottom surface of the cylindrical connecting portion 20. Like this
When the liquid passage 46 is closed by the details 22a of the rod 22, as shown in FIG. 2B, the deformable resin forming the sealing material 44 is deformed by the pressing of the details 22a,
The seal between the liquid passage 46 and the detail 22a can be completed, and leakage of the liquid material 10 can be prevented.

Moreover, since the seal member 44 is inserted into the inner bottom surface of the cylindrical connecting portion 20, the position where the seal member 44 is inserted is near the inlet of the needle pipe 18. Therefore, when the liquid passage 46 of the sealing member 44 is closed by the details 22 a of the rod 22, the amount of the liquid material 10 remaining in the cylindrical connecting portion 46 and the like can be reduced as much as possible, and the liquid drip from the needle pipe 18. The amount of the liquid material 10 flowing out due to the phenomenon can be reduced as much as possible. By the way, the sealing material 4
As the resin forming 4, any resin can be used as long as it is a resin that is deformed by the pressing force of the details 22 a of the rod 22 and has durability against the liquid material 10. Such a resin may be an elastically deformable resin, such as rubber, which returns to a substantially original shape when the stress that caused the deformation is removed, or substantially the original shape even when the stress that caused the deformation is removed. It may be a plastically deformable resin that does not return to the above.

[0017] Here, using the dispensing apparatus a viscosity at 20 ° C. shows the oil 30cp 1, pressure 2 × 10 ⁰ P
A filling experiment was performed in which the tip of the needle-like pipe 18 was inserted into the decompressed portion where the pressure was reduced in a, and a predetermined amount of oil was filled.
The compressed air pressure supplied from the compressed air nozzles 32 and 34 is adjusted so that the oil filling amount is 3 mg / time.
Zero filling experiments were performed. As a result, no liquid leakage occurred while the oil discharge was stopped. Further, the average discharge amount of the oil is 3.2 mg / time, and the variation of the discharge amount is 3.3 mg / time for the maximum discharge amount and 3.1 for the minimum discharge amount.
It was as small as mg / time, and a constant amount of oil could be discharged stably. A filling experiment was performed under the same conditions using the quantitative discharge device shown in FIG. 6 instead of the quantitative discharge device shown in FIG. The tip of the needle-shaped pipe 108 of the quantitative discharge device of FIG.
When the oil was inserted into a depressurized place where the pressure was reduced to 2 × 10 ⁰ Pa, liquid leakage frequently occurred while the oil discharge was stopped, and a discharge experiment could not be performed. In addition, the filling experiment was performed with the passage 40 of the fixed-rate discharge device being open to the atmosphere.

1 and 2, a sealing material 44 is inserted into the inner bottom surface of the cylindrical connecting portion 20, but as shown in FIG.
4 may be inserted, and as shown in FIG.
The sealing material 44 formed in close contact with the inner wall surface of the
6 may be formed. Further, as shown in FIG. 5, the rod 2 that has passed through the discharge nozzle 16 and
A seal member 45 such as a fluororesin which is deformed by contacting the inner wall surface of the cylindrical connecting portion 20 may be formed on the end face of the second detail 22a. When the sealing member 45 comes into contact with the inner bottom surface of the cylindrical connecting portion 20, the sealing member 45 closes the liquid passage 47 to the needle pipe 18 formed on the inner bottom surface of the cylindrical connecting portion 20. At that time, the sealing material 45 is deformed, and the sealing between the sealing material 45 and the liquid passage 47 can be completed.
Moreover, since the liquid passage 47 is formed on the inner bottom surface of the cylindrical connecting portion 20, when the liquid passage 47 is closed by the sealing member 45, the liquid material 10 remains only in the needle pipe 18. Without dripping as much as possible,
The variation of the discharge amount can be further reduced.

[0019]

According to the quantitative discharge apparatus according to the present invention, even when a low-viscosity liquid material is filled by inserting the tip of a needle-shaped pipe into the filling place in a reduced pressure state, the liquid material can be reliably discharged. It can be stopped, and the dripping phenomenon when the discharge of the liquid material is stopped can be made as small as possible, and the variation of the discharge amount can be made as small as possible. As a result, the metering device according to the present invention can be employed as a metering device used for lubricating oil injection into bearings of precision equipment such as watches.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view illustrating an example of a constant-rate discharge device according to the present invention.

FIG. 2 is a partial cross-sectional view illustrating a sealing material 44 shown in FIG.

FIG. 3 is a partial cross-sectional view illustrating another example of the constant-rate discharge device according to the present invention.

FIG. 4 is a partial cross-sectional view illustrating another example of the constant-rate discharge device according to the present invention.

FIG. 5 is a partial cross-sectional view illustrating another example of the constant-rate discharge device according to the present invention.

FIG. 6 is a longitudinal sectional view for explaining a conventional fixed-quantity discharge device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Liquid material 12 Syringe 14 Cylindrical body 16 Discharge nozzle 18 Needle pipe 20 Cylindrical connection part 22 Rod 22a One end of rod 22 Drive part 44, 45 Seal material 46, 47 Liquid passage

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Kazuo Kozu, Inventor 4107-5 Miyota, Miyoda-cho, Kitasaku-gun, Nagano Prefecture Inside Simeo Precision Co., Ltd. (72) Kazuo Shiba 6-11-12 Honcho, Tanashi-shi, Tokyo Citizen Watch Co., Ltd. Tanashi Factory (72) Inventor Kimio Sato 1-11-5 Tamagawacho, Akishima-shi, Tokyo No.2 Taisho Building 303 F-term in RELIAL CORPORATION (reference) 4F041 AA04 AB01 BA05 BA17 BA34

Claims (2)

[Claims] 1. A discharge nozzle of a syringe in which a liquid material to be discharged is stored, and a needle-shaped pipe having a smaller diameter than the discharge nozzle are connected by a cylindrical connecting portion, and the liquid material stored in the syringe is When a predetermined amount is discharged, one end of a rod movably inserted into the syringe is moved in the direction of the discharge nozzle so as to stop discharging the liquid material stored in the syringe from the needle pipe. And, in a fixed-rate discharge device provided with a drive unit for driving the rod so as to close the liquid passage to the needle-shaped pipe, one end of the rod is located in the discharge nozzle or in the cylindrical connecting portion. The rod is inserted into the syringe so as to be movable, and is deformed by contacting one end of the rod in a position where one end of the rod can be contacted in the discharge nozzle or the cylindrical connecting portion. A seal material made of a resin such as a fluororesin is provided, and the liquid passage having a diameter smaller than an outer diameter of one end of the rod is formed at a position where the seal material abuts on one end of the rod. Characterized quantitative discharge device. 2. A discharge nozzle of a syringe in which a liquid material to be discharged is stored, and a needle-shaped pipe having a smaller diameter than the discharge nozzle are connected by a cylindrical connecting portion, and the liquid material stored in the syringe is When a predetermined amount is discharged, one end of a rod movably inserted into the syringe is moved in the direction of the discharge nozzle so as to stop discharging the liquid material stored in the syringe from the needle pipe. And a drive unit for driving the rod so as to close the liquid passage to the needle-shaped pipe, wherein the end surface of one end of the rod has an inner wall surface of the cylindrical connecting portion. A sealing material such as a fluororesin which is deformed by contact is provided, and a liquid passage to the needle pipe is formed on an inner wall surface of the cylindrical connecting portion where the sealing material formed on the end face of the rod contacts. With In addition, the rod is inserted into the syringe such that the sealing material comes into contact with the inner wall surface of the cylindrical connecting portion and the liquid passage is closed.