KR20150107253A - atmospheric pressure nozzle device - Google Patents

Abstract

The present invention relates to a sort of atmospheric pressure nozzle device including a single cylinder wherein the center of a single partition is punched. A single tolerance hole is provided inside the cylinder to be connected to the punched hole. A check valve is provided inside the tolerance hole, wherein a non-return rod is provided in the check valve to be inserted into the punched hole. A piston connection rod is provided inside the cylinder to be covered by a spring. The cylinder is engaged with and connected to a rotary stopper which is connected to a locking stopper to be engaged with the piston connection rod. A normal pressure rod is inserted into the locking stopper to be engaged with the locking stopper and to be bonded to the cylinder. A piston is provided inside the normal pressure rod to be connected to each other. The normal pressure rod is connected to a compression head. The compression head is a nozzle extended outward.

Description

[0001] Atmospheric pressure nozzle device [0002]

The present invention relates to a kind of compression head device, and is to provide a pneumatic nozzle device installed at the inlet of a liquid container.

As is well known, liquid type products currently sold in the market are all equipped with nozzle devices in the container design. The nozzle unit uses the downward pressure method. It is widely used to extract the liquid of the liquid container because it has a merit of easy operation and a fixed flow rate because it causes the liquid stored in the bottle to flow out by changing the pressure. Covers personal cleaning products such as shampoo, shower gel or kitchen, kitchen detergent used in bathroom, and cleaning agent. Because of the wide range and diversity of the compression head device, it has become one of the most widely used technologies in the industry.

The structure of the nozzle unit has been improved by the breakthrough through the gradual research and development as the technology has been developed, but there are still problems and defects in the design of the structure which is now known. 1, the compression head 201 is designed such that the compression head 201 is generally in contact with the compression head 201 to prevent liquid from leaking when it is collided or pressed arbitrarily. So as to be locked tightly with the lower part of the body 202. However, since the compression head 201 is in a downwardly pressed state, the piston 203 in the nozzle device 200, which is generally known, is placed in the open state to allow the liquid passage 204 to pass through without any hitching. The liquid in the body 202 leaks through the liquid passage 204 or other clearance when the body 202 is in a state of inadvertently falling over.

In addition, since the general nozzle device is not designed to be watertight, water often seeps into the connection gap, causing the liquid in the bottle to deteriorate. In addition, since the general nozzle device is pressed downward and some liquid is held in the nozzle of the compression head, If there is no sucking function, the liquid that normally stays in the nozzle is slowly influenced by the earth force. This is a common defect in all currently designed nozzle arrangements.

It is a principal object of the present invention to provide a kind of pneumatic nozzle device in order to cope with the above-mentioned defects. A check valve is installed in the device to form a function of sealing the cylinder immediately after pressure is applied, do.

Another object of the present invention is to provide a kind of pneumatic nozzle device in which a vacuum suction force is generated inside the compression head when it returns to the home position, and the residual liquid remaining in the nozzle is recovered so as not to flow out, do.

It is another object of the present invention to provide a kind of pneumatic nozzle device in which one square waterproof part is provided and the square waterproof part has a raised square so as to prevent the water from sticking to the outside, This waterproof function is realized by preventing it from flowing into the cylinder.

In order to achieve the above object, the present invention is a pneumatic nozzle device, which is a single pipe body having a partition inside and a hole in the center of the partition. The cylinder has a hollow in the interior and the cylinder has a hollow that is connected to the open hole; And the check valve is provided with a stopper and a stopper, the stopper is installed at the injection port of the let-off groove, and the stopper is opened to the injection port and closed downward A check valve provided with a reciprocating motion and fitted in an open hole; A piston connecting rod which is installed in a cylinder as one hollow pipe body, a piston connecting rod provided at one end of the piston connecting rod and fitted to the inner wall surface of the cylinder; A spring used to generate a resilient force that is fitted to the pipe body of the piston connecting rod and returns to the position; A rotating cap which covers and connects to the cylinder and has an opening; A lock cap which is inserted into the cylinder as one hollow pipe body and which is fitted to the piston connecting rod; A hollow pipe body is fitted into the lock cap. The pressure rod is fitted to the lock cap, then joined to the cylinder again, and a piston connecting rod ring is provided on the inner surface of the upper push rod to hold the spring and the piston connecting rod Pushing; A piston in a hollow state connected to and connected to the upper piston, a discharge valve around the piston ring, a conduit at the bottom of the piston, a piston fitted in the cylinder and communicating therewith; And a compression head connected to and communicating with the atmospheric pressure rod, the compression head being hollow, the compression head having a nozzle extending outwardly, and the compression head having a connection pipe at the lower end and used for rotating connection with the pressure rod. Pressure nozzle unit.

Further, the present invention provides a pneumatic nozzle device, wherein the cylinder has a clamping end and a suction end, and the pipe diameter of the suction end is smaller than the pipe body of the cylinder.

Further, the present invention provides a pneumatic nozzle device in which a clamping portion is provided on the outer surface of a clamping end, and a ring plate is provided on an outer surface close to the clamping portion and used for anchoring the rotation stopper do.

In addition, the present invention relates to a pneumatic nozzle device in which a reverse rod is composed of a first rod and a second rod, and there is a gap therebetween. And a plurality of elastic bodies are connected between the first rod and the second rod.

Further, the present invention provides a pneumatic nozzle device, wherein the elastic body is formed of any one of a circular shape, a semi-circular shape, and a quadrangular shape.

In addition, the present invention provides a pneumatic nozzle device in which a chamber is provided at one end of a second one of the pneumatic nozzle devices, and is used to pull the punch through holes.

Further, in the present invention, the pneumatic nozzle device is provided with a lower end step step and an upper end step step on the outer surfaces of the two ends of the piston connecting rod, respectively, and a lower step step position is provided near the piston part do.

In the present invention, the pneumatic nozzle device includes a locking stopper having an outlet and an inlet, and a limit staircase is formed on the inner wall of the inlet. The limit staircase is connected to the locking stopper and the piston connecting rod, Pressure nozzle device according to the present invention.

In addition, the present invention provides a pneumatic nozzle device, wherein the pneumatic nozzle device is provided with a protrusion extending outwardly from a periphery of the lock cap, and is used to connect the clamping portion of the cylinder.

In addition, the present invention provides a pneumatic nozzle device, wherein one pneumatic nozzle device is provided with a lock stop screw at a position near the introduction port in the lock cap.

In addition, the present invention provides a pneumatic nozzle device, wherein the pneumatic nozzle device is provided with a fastening screw on the inner surface of the top end thereof, and is used for joining with a locking cap.

Further, in the present invention, the pneumatic nozzle device is provided with a first snap ring on the outer surface of the other end of the upper push rod, and a second snap ring on the inner surface of the connection pipe, A pneumatic nozzle device is provided.

Further, the present invention provides a pneumatic nozzle device, wherein the piston part is integrally formed with a piston connecting rod.

In addition, the present invention provides a pneumatic nozzle device in which a piston portion is fitted to a pitton connecting rod of a pneumatic nozzle device.

In addition, the present invention provides a pneumatic nozzle device, wherein the pneumatic nozzle device is provided with a rectangular waterproof portion extending upwardly from the periphery of the outlet, and the nozzle is used to achieve a waterproof function.

In order to achieve the above-mentioned object, the present invention provides a kind of pneumatic nozzle device comprising a cylinder, a pipe body, a partition, and a hole in the center of the partition. Inside the cylinder there is a tolerance groove, and the tolerance groove and the open hole are connected to each other. A fill port is formed around the fill port and a check valve is provided in the fill port. The check valve has a stopper and a stopper, the stopper is mounted at the inlet of the filler slot and the stopper is provided with a reciprocating motion to open and close down to the injection port, Used for installation. The cylinder is equipped with a piston connecting rod, which is a hollow pipe body, and a piston is installed at one end of the connecting rod of the piston, and is used to pull it into the cylinder wall. It is used to generate elasticity to return to the position by installing a spring on the pipe body of the piston connecting rod. Then, connect the cylinder with a rotation stopper, connect it with the lock stopper, and install it on the piston connecting rod. Install the upper push rod in the lock cover and attach the upper push rod to the lock cap, then connect it with the cylinder to connect with each other. On the inner side of the upper barrel there is a piston barrel hook, which is used for the interaction of the spring and piston barrel, and the piston is installed in the upper barrel and connected to it. There is a discharge valve around the ring of the piston and a conduit at the bottom of the piston, which is fitted in the cylinder and used to connect with it. Finally, the pressure rod and the compression head are connected and connected with each other. The compression head is a nozzle that is hollow and extends outward. At the end of the compression head, there is a connecting pipe, which is used to connect the pressure rod and the piston is included in it.

In order to more easily understand the above and other objects, features and advantages of the present invention, a detailed description will be given of a combination of excellent examples and pictures that are compared below.

1 is a structural cross-sectional view of a conventional pneumatic nozzle apparatus.
Figs. 2 (a) to 2 (b) are three-dimensional structural analysis and analysis observation views of the present invention.
3 is a combination diagram of the present invention.
4 (a) to 4 (c) are explanatory views of the operation of the present invention.
Fig. 5 is a view for explaining another operation of the present invention. Fig.
6 (a) to 6 (c) are sectional views of another example of the structure of the present invention.
Fig. 7 is a cross-sectional view of another embodiment of the present invention. Fig.

The pneumatic nozzle device applied to the present invention is constructed as shown in Figs. 2 to 7.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

First, the present invention refers to Figs. 2 (a) to 2 (b). 3 is a three-dimensional structural analysis and analysis observation view of the present invention. As shown in the drawings, the pneumatic nozzle apparatus of the present invention includes one cylinder 1, which is a pipe body. The cylinder 1 has a clamping end 11 and a suction end 12 and in this embodiment the pipe diameter of the suction end 12 is smaller than the pipe body of the cylinder 1 and the outer surface of the clamping end 11 A clamping portion 13 is provided. A ring plate 14 is provided on the outer surface near the position of the clamping portion 13 and a partition 15 is provided in the suction end 12 and a hole 151 is formed in the center of the partition 15. [ In the interior of the cylinder 1, there is a receiving groove 16, and the receiving groove 16 and the opened hole 151 of the partition 15 are connected to each other. An inlet (17) is formed around the filled cavity (16) and a check valve (2) is provided in the filled cavity (16). The check valve 2 has a stopper 21, and in this embodiment, the stopper 21 is circular. The stopper section 21 is provided at the inlet 17 of the accommodating groove 16 and also provides a reciprocating motion in which the stopper section 21 is opened to the inlet 17 and closed downward. The bottom part of the stopper 21 is connected to the reverse stopper rod 22 and the reverse stopper rod 22 is composed of the first hooker 221 and the second hooker 222 and there is a gap therebetween. A plurality of elastic bodies 223 are connected between the first hook 221 and the second hook 222 so that the elastic body 223 is capable of pulling the stopper 21 properly so that the stopper 21 is inserted into the inlet 17, . In addition, in this embodiment, the elastic body 223 is in a circular state, the second rod 222 is fitted in the hole 151, and the chamfer 224 is installed at one end of the second rod 222, The hook body 222 is inserted into the hole 151 and is not influenced by the chamfer 224 so as not to be separated. In addition, the cylinder 1 is provided with a piston connecting rod 3, and the piston connecting rod 3 is a hollow pipe body. A piston portion 31 is provided at one end of the piston connecting rod 3. In this embodiment, the piston portion 31 is integrally formed with the piston connecting rod 3. [ The piston 31 is fitted to the inner wall surface of the cylinder 1 and is provided with a lower end stepped step 32 on the outer surface of the rod of the piston connecting rod 3 close to the piston 31, And an upper stop step 33 is provided on the outer surface of the one end of the hook. A spring 34 is fitted to the piston connecting rod 3, and the spring 34 is used to generate elasticity to return to the home position.

2 (a) to 2 (b). The rotary stopper 4 is provided with an opening 41 and a screw 42 is provided on the inner surface of the rotary stopper 4. The rotary stopper 4 is connected to the cylinder 1 by covering the rotary stopper 4. [ The screw 42 can be connected to the sickle (not shown in the figure) by connecting the rotary cap 4 and the cylinder 1 to the ring plate 14. The rotation stopper 4 is connected to the lock stopper 5 and the lock stopper 5 is used to fit the clamping end 11 of the cylinder 1 as a hollow pipe body and is fitted in the piston connecting rod 3. The lock stopper 5 has an outlet 51 and an inlet 52. A limit staircase 53 is formed on the inner wall of the inlet 52. The limit staircase 53 has a lock cap 5, (3) and then engaged with the lower end stepped step (32). A lock stopper screw 54 is provided at a position near the introduction port 52 in the lock stopper 5 and a protrusion 55 extending outwardly is provided around the lock stopper 5, And is used to engage with the clamping portion 13. The square waterproofing part 56 is installed to extend upwardly around the outlet 51 and has a rectangular shape rising high in the square waterproofing part 56. Therefore, water is prevented from flowing to the outside of the cylinder (1) when the water is used, so that the nozzle has a waterproof function. The upper stopper rod 6 is fitted to the lock cap 5 with the upper push rod 6 sandwiched therebetween. The upper push rod 6 is a hollow pipe body. The upper push rod 6 is fitted to the outlet 51 of the lock cap 5 and then joined to the cylinder 1 and connected to each other. In addition, there is a piston connecting rod ring 61 on the inner surface of the upper push rod 6 and a piston connecting rod ring 61 is used to engage the spring 34 and the upper stopping step 33, respectively. A fastening screw 62 is provided on the inner surface of one end of the upper push rod 6 and the fastening screw 62 is used to engage with the locking stop screw 54. A first snap ring 63 is provided on the outer surface of the other end of the upper push rod 6. The upper pressure rod 6 is provided with a piston 7 and the inside of the piston 7 is hollow and connected to the upper push rod 6. A discharge valve 71 is provided in the vicinity of the ring of the piston 7 and a conduit 72 is provided at the bottom of the piston 7 so as to be fitted into the cylinder 1 and used to connect with the piston 7. Finally, the compression head 8 is connected to the upper push rod 6 and communicated therewith. The compression head 8 is in a hollow state and the compression head 8 has a nozzle 81 extending outwardly and a connecting pipe 82 at the lower end of the compression head 8. A second snap ring 83 is provided on the inner surface of the connecting pipe 82 and used to engage with the first snap ring 63 of the upper push rod 6 and to include the piston 7 therein. The combination completeness is as shown in FIG.

4 (a) to 4 (c). And is a sequential illustration of the operation explanatory diagram of the present invention. As shown in FIG. 4 (a), when the compression head 8 is pushed downward, the upper push rod 6 is pulled to move to the region indicated by S1 in the figure and at the same time, the piston of the piston connecting rod 3 The portion 31 stops due to the frictional force of the inner wall surface of the cylinder 1 and does not move. At this time, as the compression head 8 moves downward, the discharge valve 71 of the piston 7 gradually communicates with the nozzle 81 and the compression head 8 moves to the (S1) So that the discharge valve 71 completely coincides with the nozzle 81. As shown in Fig. At this time, due to the pressure, the stopper 21 of the check valve 2 faces downward to close the injection port 17. 4 (b), after the compression head 8 enters the zone S2, the compression head 8 guides the upper push rod 6 and presses the spring 34 to release the screw The air in the cylinder 1 after the piston 62 is engaged with the lock cap screw 54 of the lock cap 5 causes the piston 31 of the piston connecting rod 3 to press the space of the cylinder 1 81, and also the liquid to be drawn out from the nozzle 81 is led out. When the compression head 8 is about to return to the home position as shown in Fig. 4 (c), the upper push rod 6 receives the resiliency of the spring 34 and moves upwardly to the piston portion 31 of the piston connecting rod 3, Is stopped due to the frictional force of the inner wall of the cylinder 1 and does not move. The compression rod 8 and the upper push rod 6 are continuously moved upward so that the piston connecting rod hook 61 of the upper push rod 6 is hooked on the upper stop step 33 of the piston connecting rod 3 and the piston connecting rod 3 And at the same time, the upper pressure bar 6 closes the discharge valve 71 of the piston 7. Finally, the lower step stop 32 of the piston connecting rod 3 and the limit step 53 of the lock stopper 5 are floated with respect to each other to stop and return to the home position. At the same time, as the space of the cylinder 1 is increased, the liquid flows in the receiving groove 16 through the opened hole 151 in response to the pressure, thereby pushing the stopper piece 21 open, gradually opening the injection port 17 The liquid is allowed to enter the cylinder 1 through the check valve 2, and then prepared for blowing out the raw material.

In addition, when the compression head 8 returns to the home position, the discharge valve 71 is gradually closed, and the pressure in the space inside the compression head 8 is gradually increased to produce a vacuum suction force, Which causes the liquid to return to its original state. Thereby preventing the liquid inside the nozzle 81 from flowing out due to the influence of the earth attraction.

See FIG. Fig. 2 is a sequential illustration of another operation explanatory view of the present invention. Fig. As shown in the drawings, the pneumatic nozzle device of the present invention also has functions of locking, leakage prevention, and flow stop. The pressure head 8 is moved downward by moving the compression head 8 as shown in FIG. 5 to pass through the areas S1 and S2 and then the pressure head 8 is rotated in the clockwise direction to the area S3, So that the screw 62 on the inner surface of the lock cap 6 and the lock cap screw 54 of the lock cap 5 are locked. At this time, the check valve 2 is pushed by the piston connecting rod 3 to allow the filler groove 16 of the cylinder 1 to deform and fill the elastic body 223 to form a sealed state, do.

6 (a) to 6 (c). Sectional structure of another embodiment of the present invention. The elastic body 223 provided on the check valve 2 can be designed in the form shown in Fig. 6 (a) in addition to the circular state in the above-described execution example, and the elastic body 223 can be designed in a semi-circular shape as shown in Fig. 6 (b) 6 (c). Reference is made to another exemplary structural cross-sectional view of Fig. The piston portion 31 at one end of the piston 7 and the piston connecting rod 3 described above are integrally formed and can also be designed by fitting the piston portion 31 to one end of the piston connecting rod 3.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

It is to be understood that the invention is not to be limited to the specific forms thereof which are to be described in the foregoing description, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

The technical idea of the pneumatic nozzle device according to the present invention is that the same results can be repeatedly practiced. Particularly, by implementing the present invention as described above, it is possible to contribute to industrial development by promoting technological development,

Description of the Related Art
1: Cylinder
11: Clamping stage 12: Suction stage
13: clamping part 14:
15: partition 151: hole
16: allowance groove 17: inlet
2: Check valve
21: Stopper 22: Reverse jib
221: first hook 222: second hook
223: elastic body 224: chamfer
3: Piston connecting rod
31: piston part 32: lower jersey stairs
33: upper jersey stairs 34: spring
4: Rotation stopper
41: opening 42: screw
5: Lock cap
51: outlet 52: inlet
53: Limit stairs 54: Lock cap screw
55: projection part 56: square waterproof part
6: Upper rod
62: Fast screw 61: Piston rod connection
63: First snap ring
7: Piston
71: discharge valve 72: conduit
8: Compression head
81: nozzle 82: connecting pipe
83: Second snap ring

Claims (15)

As a pneumatic nozzle device,
As one pipe body, it has a partition inside, and there is a hole in the center of the partition. A cylinder (1) in which a cylinder has a cylinder cavity (1);
And the check valve is provided with a stopper and a stopper, the stopper is installed at the injection port of the let-off groove, and the stopper is opened to the injection port and closed downward A check valve (2) provided with a reciprocating motion and fitted with an inverted bobbin in an open hole;
A piston connecting rod (3) provided in a cylinder as one hollow pipe body, provided with a piston portion at one end of the piston connecting rod and fitted to the inner wall surface of the cylinder;
A spring (34) used to generate a resilient force that is fitted to the pipe body of the piston connecting rod and returns to the position;
A rotating cap (4) covering and connecting to the cylinder and having an opening;
A lock cap (5) fitted in the cylinder as one hollow pipe body and fitted to the piston connecting rod;
A hollow pipe body is fitted into the lock cap. The pressure rod is fitted to the lock cap, then joined to the cylinder again, and a piston connecting rod ring is provided on the inner surface of the upper push rod to hold the spring and the piston connecting rod A push rod 6;
A piston (7) installed in the upper pressure rod as a hollow state and connected to the piston, a discharge valve around the piston of the piston, and a conduit at the bottom of the piston, And
And a compression head (8) connected to and communicating with the pressure rod, the compression head being hollow, the compression head having a nozzle extending outwardly and the compression head having a connecting pipe at the lower end and used for rotating connection with the pressure rod Pressure nozzle device.
The method according to claim 1,
Wherein the pressure-type nozzle device has a clamping end and a suction end in the cylinder, and a pipe diameter of the suction end is smaller than a pipe body of the cylinder.
The method of claim 2,
The pneumatic nozzle device according to claim 1, wherein a clamping portion is provided on an outer surface of the clamping end, and an annular plate is provided on an outer surface near the clamping portion and used to anchor the rotation stopper.
The method according to claim 1,
The pneumatic nozzle unit is composed of a first rod and a second rod, with a gap therebetween. Wherein a plurality of elastic bodies are connected between the first rod and the second rod.
The method of claim 4,
The pressure-type nozzle device according to claim 1, wherein the elastic body is any one of a circular shape, a semi-circular shape, and a quadrangular shape.
The method of claim 4,
The pneumatic nozzle device is characterized in that a chamfer is provided at one end of the second one of the pneumatic nozzles and is used to pull the punch hole.
The method according to claim 1,
Wherein the pneumatic nozzle device comprises a lower end stepped step and an upper end stepped step on the outer surfaces of two ends of the piston connecting rod, respectively, and a lower stepped step position is provided near the piston part.
The method of claim 7,
In the pneumatic nozzle device, the locking stopper has an outlet and an inlet, and a limit staircase is formed on the inner wall of the inlet. The limit staircase is connected to the locking stopper and the piston connecting rod, Pressure nozzle.
The method of claim 3,
Wherein the pneumatic nozzle device is provided with a protruding portion extending outwardly from a periphery of the lock cap, and is used to connect with a clamping portion of the cylinder.
The method of claim 8,
Wherein the air pressure type nozzle device is provided with a lock stop screw at a position near the introduction port in the lock cap.
The method of claim 10,
Wherein the pneumatic nozzle device is provided with a fastening screw on the inner surface of the top end thereof and is used for joining with a locking cap.
The method according to claim 1,
The pneumatic nozzle device is provided with a first snap ring on the outer surface of the other end of the outer barrel and a second snap ring on the inner surface of the connecting pipe for use in connection with the first snap ring .
The method according to claim 1,
Wherein the pneumatic type nozzle device comprises a piston part integrally formed with a piston connecting rod.
The method according to claim 1,
Wherein the pneumatic type nozzle device is installed by fitting the piston part into the pitton connecting rod.
The method of claim 8,
Wherein the pneumatic nozzle device is provided with a rectangular waterproof portion extending upwardly from the periphery of the outlet, and the nozzle is used to achieve a waterproof function.

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