KR101733605B1 - Nozzle device for dispenser to distribute impact-collision - Google Patents

Abstract

The present invention relates to a nozzle device for a dispenser to distribute impact and collision, and more specifically, to a nozzle device for a dispenser to distribute impact and collision which includes an inclined supporting unit (40) where inclined surfaces (41, 42) touch each other on the lower side of a nozzle (35) and the upper side of a nozzle cover (38) to the upper and lower directions. The impact and the collision repeated on the upper side of the nozzle (35) are dispersed by the inclined supporting unit (40) where the inclined surfaces (41, 42) touch each other on the lower side of the nozzle (35) and the upper side of the nozzle cover (38) to the upper and lower directions, using the front end of a tappet (12) to support the upper side of the nozzle (35), when an operation for spraying a dispenser liquid is performed by the vertical vibration of the tappet (12). Therefore, partial damage on the nozzle and the nozzle cover can be minimized compared to conventional cases, and excellent durability can be provided.

Description

TECHNICAL FIELD [0001] The present invention relates to a collision impact dispersion type dispenser nozzle device,

The present invention relates to a dispenser nozzle apparatus, and more particularly, to a dispenser nozzle apparatus for preventing a nozzle and a nozzle cover from being damaged by forming a support structure in which a nozzle and a nozzle cover abut an inclined surface in a vertical direction, To a collision impact dispersion dispenser nozzle device.

In general, a high-precision dispenser is a device for spraying a dispenser liquid to a target object by a predetermined amount through a nozzle, and is widely used for coating or bonding a specific site in precision industries such as semiconductors and mobile phones.

1 and 2, the high-precision dispenser includes a driving unit 2 in which the tappet 3 vibrates up and down by a vibrating means, and a syringe 5 coupled to a bottom surface of the driving unit 2, A body part 4 for supplying the dispenser liquid to the outflow hole 4a and an outlet hole 4a of the body part so that a certain amount of the dispenser liquid is injected to the outside through the nozzle hole, And a nozzle means (6).

The nozzle means 6 is connected to the outlet hole 4a of the body portion and has a guide 7 formed with an operation hole 7a for moving the tappet vertically and oscillatingly therein, A nozzle 8 in which a nozzle 8a is formed and a nozzle cover 9 screwed to the body 4 to cover the nozzle.

In this conventional high precision dispenser, the dispenser liquid filled in the syringe 5 is supplied into the nozzle means 6 through the outflow hole of the body portion. At this time, the dispenser liquid has the nozzle hole 8a due to viscoelasticity . In this state, when the tip of the tappet contacts the upper surface of the nozzle hole 8a of the nozzle while the tappet 3 vibrates up and down by the vibrating means, the dispenser liquid is sprayed through the nozzle hole 8a, The dispenser liquid is dispensed and the dispenser liquid is supplied again, so that a certain amount of the dispenser liquid is continuously sprayed.

On the other hand, the high-precision dispenser described above can not effectively dispense the dispenser solution because the pressure spray is weak when the sprayed liquid is used for an epoxy application having a higher viscosity or a higher squeeze property.

3 and 4, it is possible to sharpen the tip end 3 'of the tappet 3 to reduce the contact area of the dispenser liquid, thereby increasing the injection pressure.

In order to smoothly introduce the dispenser liquid into the nozzle hole together with the improvement of the structure of the tappet 3, a receiving portion 8b and an insertion groove portion 8b into which the tip portion of the tappet is inserted are formed on the nozzle hole 8a of the nozzle 8 The liquid inflow grooves 8d are formed in a vertical circumferential position between the accommodating portion 8b and the insertion groove portion 8c at a constant circumferential position to smoothly supply the dispenser liquid 8d The performance of the high-pressure dispenser continues to be improved.

However, in the above-described high-pressure dispenser, due to the high pressure, the impingement of the tappet on the upper portion of the nozzle during operation of the up-down vibration is higher than that of the conventional tappet, and the dispenser liquid has high viscoelasticity. And the nozzle cover for supporting the nozzle and the nozzle is partially broken.

That is, due to the structure in which the step portion 8-1 outside the nozzle 8 is partially supported at the support step 9-1 of the nozzle cover 9, the impact impact of the tappet applied to the upper portion of the nozzle is not dispersed The nozzle cover can be easily broken while being partially concentrated on the stepped portion of the nozzle and the supporting step of the nozzle cover.

Such a problem is more likely to occur in the high-pressure dispenser but also in a high-precision dispenser.

Patent Document 1: Patent Registration No. 10-1190939 Patent Document 2: Patent Registration No. 10-1165557 Patent Document 3: Patent Registration No. 10-1175284 Patent Document 4: Japanese Patent Application Laid-Open No. 10-2013-0076581

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a nozzle structure and a nozzle cover, in which a support structure in which a nozzle and a nozzle cover are inclined in a vertical direction are formed, So as to prevent partial breakage.

It is another object of the present invention to prevent partial collapse of the nozzle and the nozzle cover by buffering the collision impact between the metal by inserting the O-ring into the supporting structure in which the nozzle and the nozzle cover abut each other.

The present invention relates to a tappet of the present invention, which comprises a driving part for vibrating the tappet up and down by vibrating means, a body part coupled to the bottom surface of the driving part and supplying the dispenser liquid to the outflow hole by a syringe at one side, And a nozzle means for spraying a predetermined amount of the dispenser liquid through the nozzle hole by contact with the upper and lower vibration, wherein the nozzle means is inserted and connected to the outlet hole of the body portion, And a nozzle cover screwed to the body portion to cover the nozzle so as to support the nozzle, wherein the nozzle cover has a lower portion for spraying a predetermined amount of the dispenser liquid, And an inclined support portion formed on an upper portion of the nozzle cover so that the inclined surfaces thereof abut against each other in the vertical direction. So that the collision impact due to the up-and-down vibration of the pit is distributed and supported.

The nozzle cover according to the present invention is characterized in that a ring-shaped groove portion is formed on an inclined surface of the nozzle cover, and an O-ring for buffering the inclined surface of the nozzle is inserted into the groove portion.

According to the present invention, the lower portion of the nozzle and the upper portion of the nozzle cover form an inclined support portion in which the inclined surfaces are in contact with each other so as to disperse the collision impact caused by the up- The partial breakage is minimized.

In addition, according to the present invention, an O-ring is inserted into a groove formed on an inclined surface of the nozzle cover to buffer impact impact between the metal, thereby further preventing partial destruction of the nozzle and the nozzle cover.

1 is a front view showing the overall structure of a conventional high-precision dispenser;
2 is an enlarged view of the main part of Fig.
3 is a cross-sectional view showing another embodiment of a conventional nozzle;
Figure 4 is a nozzle plan view of Figure 3;
FIG. 5 is a front view showing the entire configuration of a dispenser to which the present invention is applied; FIG.
6 is an enlarged view of the main part of Fig.
Figure 7 is an assembled cross-sectional view of the nozzle and nozzle cover of Figure 6;
FIG. 8 is an exploded partial cross-sectional view of FIG. 7. FIG.
Fig. 9 is a longitudinal sectional view of the present invention; Fig.
10 is a cross-sectional view showing another embodiment of the present invention.

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

The impact impingement dispenser nozzle device of the present invention comprises a driving part 10 in which a tappet 12 is vertically oscillated and operated by a vibrating means as shown in FIGS. 1 to 9 and a driving part 10 which is coupled to a bottom surface of the driving part 10 A body portion 20 for supplying the dispenser liquid to the outflow hole 21 by a syringe 25 on one side and a discharge port 21 connected to the outflow hole 21 of the body portion, The nozzle means 30 is inserted into and connected to the outflow hole 21 of the body portion and has an operation hole 31a in which the tappet moves vertically and oscillates, A nozzle 35 coupled to the front portion of the guidance and having a nozzle hole 35a formed at the center thereof and a nozzle cover 35 screwed to the body portion 20 to cover the nozzle to support the nozzle, (38).

Particularly, an inclined supporting portion 40 is formed on the lower portion of the nozzle 35 and the upper portion of the nozzle cover 38 so that the inclined surfaces 41 and 42 abut against each other in the vertical direction, So as to be dispersed and supported.

In other words, since the support structure that maximizes the area in which the nozzle 35 and the nozzle cover 38 are supported in the vertical direction is dispersed and supported by collision impact caused by the vertical vibration of the tappet 12, the nozzle and the nozzle cover are prevented from being damaged .

10, a ring-shaped groove 43 is formed in the inclined surface 42 of the nozzle cover 35 and an O-ring (not shown) for buffering the inclined surface 41 of the nozzle 35 is formed in the groove 43 45).

At this time, the O-ring 45 may be installed at a plurality of positions as well as a single position as shown in the drawing. In addition, the O-ring 45 is preferably formed in a circular cross-sectional structure. It is needless to say that the portion of the O-ring 45 that contacts the sloping surface 41 of the nozzle may be formed into a surface shape so as to support the surface contact.

The tip portion 12a of the tappet 12 is sharpened so as to reduce the contact area of the dispenser liquid so as to increase the injection pressure so that the receiving portion 35b is formed above the nozzle hole 35a of the nozzle 35, And the insertion groove portion 35c into which the tip end portion of the tappet is inserted are formed in a funnel shape having a stepped section and a liquid inlet groove 35b is formed in the vertical position between the accommodating portion 35b and the insertion groove portion 35c at an isosceles- Pressure type structure in which the dispenser liquid is supplied smoothly.

It is preferable that the present invention is applied to a dispenser of a high pressure type as shown in the drawing, but it goes without saying that it can be applied to a dispenser of a high precision type rather than a high pressure.

Reference numeral 31b denotes a packing obtained by airtight coupling of guidance, 38a denotes a screw portion of the nozzle cover, and 38b denotes a nozzle coupling hole of the nozzle cover, respectively.

Hereinafter, the operation and operation of the present invention will be described.

A dispenser nozzle device according to the present invention includes a guide portion 31 inserted into a lower portion of a nozzle hole 21 of a body portion 20 and a nozzle 35 and a nozzle cover 38 covering the nozzle, And then screwed to the body portion to assemble.

At this time, the lower part of the nozzle 35 and the inclined surfaces 41 and 42 of the upper part of the nozzle cover 38 are supported in a vertical direction.

The dispenser liquid filled in the syringe 25 is poured into the funnel-shaped receiving portion 35b and the insertion groove portion 35c on the upper portion of the nozzle 35 through the outlet hole 21 of the body portion 20 .

9, when the tip portion 12a of the tappet contacts the upper portion of the insertion groove portion 35c of the nozzle while the tappet 12 of the drive portion 10 vibrates up and down by the vibrating means, And the dispenser liquid is supplied again to the insertion groove portion 35c when the tip end portion 12a of the tappet is separated from the insertion groove portion 35c of the nozzle so that a certain amount of dispenser liquid is continuously sprayed It will be done.

That is, the tappet 12 of the driving unit 10 repetitively vibrates a certain amount of dispenser liquid through the nozzle hole 35a of the nozzle 35 while repeatedly vibrating up and down.

In this process, the tappet 12 of the driving unit 10 repeatedly collides with the upper part of the nozzle by the up-and-down vibration, so that the impact is applied.

At this time, the lower portion of the nozzle 35 and the inclined surfaces 41 and 42 on the upper portion of the nozzle cover 38 are formed to be wider in the vertical direction so as to support the inclined support portion 40, The nozzles 35 and the inclined surfaces 41 and 42 of the nozzle cover 38 are supported in a wide area to support and disperse the impact as much as possible.

This prevents the nozzle 35 and the nozzle cover 38 from being damaged as in the prior art.

An O-ring 45 is inserted into the ring-shaped groove 43 formed by the inclined surface 42 of the nozzle cover 35 so that the inclined surface 41 of the nozzle 35 cooperates with the inclined surface 42 of the nozzle cover And the O-ring 45 is used to support the pad so that the above-described pad is shock-absorbed and supported by the O-ring 45 together with the impact dispersion by the inclined support 40 against the impact caused by the up- The effect of canceling the impact is multiplied, so that the support portions of the nozzle 35 and the nozzle cover 38 are more effectively prevented from being damaged as in the conventional art.

In the present invention, the collision impact of the nozzle 35 and the nozzle cover 38 further increases in the case of a high-pressure dispenser that forms a high-pressure injection pressure as well as a high-precision dispenser, The impact is canceled by the nozzle 35 and the impact-dispersed inclined support portion 40 of the nozzle cover 38, thereby further improving the durability of the component.

10: driving part 12: tappet
20: body portion 21: outflow hole
25: syringe 30: nozzle means
31: guidance 31a: outflow ball
35: nozzle 35a: nozzle ball
38: cover 40: tilting support
41, 42: sloped surface 43:
45: O ring

Claims (2)

A tappet 12 which vibrates up and down by vibrating means and which is connected to the bottom of the drive unit 10 and which supplies the dispenser liquid to the outflow hole 21 by means of a syringe 25 on one side, And a nozzle means (30) coupled to the outflow hole (21) of the body portion for spraying a predetermined amount of dispenser liquid through the nozzle hole by contact with the tappet by vertical vibration, The means 30 includes a guiding 31 inserted into and connected to the outlet 21 of the body and having an operating hole 31a through which the tappet 12 is oscillated up and down, And a nozzle cover 38 screwed to the body 20 in such a manner as to cover the nozzle so as to cover the tip end 12a of the tappet 12, To make the injection pressure higher by reducing the contact area of dispenser liquid by sharpening A receiving portion 35b and an insertion groove 35c into which the tip of the tappet is inserted are formed in a funnel shape above the nozzle hole 35a of the nozzle 35, Pressure type structure in which liquid dispensing grooves 35d are formed in the vertical direction at an equiangular position in the circumferential direction between the grooves 35c so that the dispenser liquid is smoothly supplied and the dispenser nozzle device for spraying a certain amount of dispenser liquid ,
An inclined supporting portion 40 is formed on the lower portion of the nozzle 35 and the upper portion of the nozzle cover 38 so that the inclined surfaces 41 and 42 abut against each other in the vertical direction, And wherein the dispenser nozzle device is configured to dispense the droplets.
The method according to claim 1,
An annular groove 43 is formed in the inclined surface 42 of the nozzle cover 38 and an O-ring 45 for buffering the inclined surface 41 of the nozzle 35 is inserted into the groove 43 Wherein the dispenser nozzle device is a collision impact dispensing dispenser nozzle device.

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