KR200204381Y1 - Compression rod for compressing-type vaporizer - Google Patents

Abstract

The present invention allows the air to flow smoothly into the cylinder during the suction stroke of the compression rod, thereby increasing the amount of air compression during compression, and improving the air inflow structure to prevent the lubricant from drying out quickly and to improve the life of the compression O-ring and cylinder. The present invention relates to a compressed rod of an automatic spraying machine, which extends and prevents lubricating oil from being mixed into a solution and adversely affecting crops or plants.

The configuration of the present invention is provided with a handle 21 is inserted into the cylinder 30, the lower portion of the piston (22) is fitted with a piston (50) equipped with a compression O-ring 40 is bolted to the nut 60 is protruded In the compression rod 20, the fixing rod 23 formed on the upper portion of the bolt 22 smaller than the outer diameter of the compression rod 20 and larger than the outer diameter of the bolt 22, the O-ring 70 in the fixing rod 23 ) And the piston 50 to be assembled, and to secure the movement gap (G) so that the piston 50 can be moved up and down in the fixing rod 23, the fixing rod 23 and the bolt 22 of the The air passage 24 is formed perpendicular to the outside.

Description

Compression rod for compressing-type vaporizer

The present invention relates to a compression type automatic spraying machine, and more particularly, to allow air to flow smoothly into the cylinder during the suction stroke of the compression rod, thereby increasing the amount of air compression during compression, and improving the inflow structure of the air so that the lubricant dries quickly. The present invention relates to a compression rod of a compressed automatic spraying machine which prevents damage and prolongs the life of a compression O-ring and a cylinder, and prevents lubricating oil from being mixed into the solution and adversely affecting crops or plants.

Generally, as shown in FIGS. 1 to 3B, the compressed automatic spraying machine includes a door container 1 in which a solution such as a disinfectant solution, pesticide, nutrient, water, etc. is accommodated, and a cylinder built in the center of the spray bottle 1 ( 2) a compression rod 3 inserted into the up and down reciprocating motion, a spout stopper 4 coupled to the spout of the spray bottle 1, and a safety pin installed at the spout stopper 4 to discharge compressed air; (5), it is composed of an injector (8) connected to the spray bottle (1) by a hose (6) for injecting a solution through the injection nozzle (7).

Meanwhile, as illustrated in FIGS. 2 and 3A and 3B, a handle 3a is integrally formed at an upper portion of the compression rod 3 fitted into the cylinder 2, and a piston () is disposed at the lower portion of the compression rod 3. A bolt 3b into which the 10 is fitted protrudes integrally, and a nut 11 that prevents detachment of the piston 10 is coupled to the bolt 3b by screwing. A ring groove 10a and a through hole 10b are formed in the piston 10, and the compression o-ring 12 is inserted into the ring groove 10a so as to be movable up and down.

However, in the conventional compression rod 3 configured as described above, air flows into the through hole 10b through the piston 10 and the cylinder 2 as shown in FIG. 3A when the suction stroke (when the compression rod is pulled upward). Because of this, there were the following problems.

That is, when the air is introduced, the lubricant on the inner wall of the cylinder 2 is scraped up by the compression o-ring 12 and enters the inside together with the air flowing into the cylinder 2, so that the lubricant on the inner wall of the cylinder 2 is wiped clean. It dries quickly, which causes the compression o-ring 12 and the inner wall of the cylinder 2 to be damaged, thereby shortening the life of the compression o-ring 12 and the cylinder 2.

In addition, if lubricant oil is frequently injected into the compression rod 3 in order to prolong the wear of the compression o-ring 12 and the cylinder 2 described above, the lubricant oil continuously flows into the interior of the spray bottle 1 to disinfect liquid, pesticide, There is a problem in that a bad effect on the crops or plants because it is sprayed by mixing in a solution such as nutrients, water.

In addition, conventionally, since the air does not flow into the cylinder 2 smoothly during the suction stroke, the air is not filled in the cylinder 2, and a vacuum is formed at about ⅓ so that the amount of air compression during compression is reduced. There was a problem, and because of this inconvenience to pump a lot.

The object of the present invention is to solve the above-mentioned drawbacks as described above, and to smoothly inflow air into the cylinder during the suction stroke of the compression rod to increase the amount of air compression during compression, and also to improve the air inlet structure This prevents the lubricant from drying out quickly and extends the life of the compressed O-rings and cylinders.The compressed rod of the automatic self-atomizing machine is designed to prevent the lubricant from entering the solution and adversely affecting crops and plants. To provide.

In order to achieve the above object, the present invention is integrally formed with a fixed rod into which the piston is movable up and down on the upper part of the bolt of the compression rod, and secures a moving gap so that the piston can be moved up and down in the fixed rod. On the outside of the fixed rod and bolt is formed an air passage for smoothly inlet air during intake stroke.

1 is a perspective view of a compressed automatic atomizer.

Figure 2 is an exploded perspective view of a conventional compression rod.

Figure 3a is an assembled cross-sectional view showing an operating state in the suction stroke of the conventional compression rods.

Figure 3b is an assembled cross-sectional view showing an operation state in the compression stroke of the conventional compression rods.

Figure 4 is an exploded perspective view of the present invention.

5 is an assembled cross-sectional view of the present invention.

Figure 6a is a state of operation during the suction stroke of the compression rod according to the present invention.

Figure 6b is an operating state during the compression stroke of the compression rod according to the present invention.

FIG. 7 is a cross-sectional view taken along the line AA of FIG. 4. FIG.

Figure 8a is a perspective view showing another embodiment of the air passage according to the present invention.

8B is a cross-sectional view taken along the line BB of FIG. 8A.

<Code Description of Main Parts of Drawing>

20: compression rod 21: handle

22: bolt 23: fixed rod

24: air passage 30: cylinder

40: compressed O-ring 50: piston

60: nut 70: O-ring

G: moving gap

Hereinafter, the technical configuration of the present invention in detail according to the accompanying drawings.

The present invention, as shown in Figure 4 to 8b, is provided with a handle 21 is inserted into the cylinder 30, the lower portion of the piston 50 equipped with a compression O-ring 40 is fitted into the nut 60 In the compression rod 20 protruding the bolt 22 is fastened, forming a fixed rod 23 on the upper portion of the bolt 22 is smaller than the outer diameter of the compression rod 20 and larger than the outer diameter of the bolt 22. The O-ring 70 and the piston 50 are assembled to the fixing bar 23, but the moving rod G is secured to the fixing bar 23 so that the piston 50 can be moved up and down. The air passage 24 formed perpendicular to the outside of the 23 and the bolt 22 is a basic feature of the technical configuration.

Here, the compression rod 20 is inserted into the cylinder 30 to reciprocate up and down, as shown in FIG. 6a, when the compression rod 20 is pulled upward, a suction stroke for introducing new air into the cylinder 30 is made. 6B, a compression stroke for compressing air introduced into the cylinder 30 is made by pushing the compression rod 20 downward.

The fixed rod 23 is formed integrally with the lower portion of the compression rod 20, the O-ring 70 and the piston 50 is sequentially inserted in the fixed rod 23, the O-ring 70 is fixed The piston 50 is fitted to the rod 23 and is fixed at the top, and the piston 50 is movable up and down through the movement gap G secured in the fixing rod 23.

The O-ring 70 fitted to the fixing rod 23 blocks the air in the cylinder 30 from leaking to the outside through the air passage 24 during the compression stroke.

The bolt 22 is formed integrally with the lower portion of the fixing rod 23, the outer diameter of the bolt 22 is formed smaller than the outer diameter of the fixing rod 23, so the nut 60 is only to the top of the bolt 22 In the fastened state, the piston 50 is placed on the upper portion of the nut 60.

The piston 50 is formed with a ring groove 51 into which the compression o-ring 40 is fitted. In this design, the compression o-ring 40 is fixed to the ring groove 51 so that the compression o-ring 40 does not move up and down.

On the other hand, in the embodiment of the present invention, a plurality of air passages 24 are formed on the outside of the fixed rod 23 and the bolt 22 so that air flows more smoothly during the suction stroke.

8A and 8B illustrate another embodiment of the air passage 24 according to the present invention. As shown, the fixed rod 23 and the bolt 22 are cut into the '+' shape to form the air passage 24. May be formed.

When described in detail according to the accompanying drawings the overall operating relationship of the present invention is configured as follows.

First, as shown in FIG. 6A, when the compression rod 20 is pulled upward in the suction stroke, the compression o-ring 40 in close contact with the inner diameter of the cylinder 30 is raised while the nut 60 contacts the piston 50. At this time, since the O-ring 70 and the piston 50 are kept spaced apart through the moving gap G secured in the fixing rod 23, new air is applied to the fixing rod 23 and the bolt 22 as shown in the arrow. It smoothly flows into the cylinder 30 through the formed air passage 24.

Next, as shown in FIG. 6B, when the compression rod 20 is pushed downward in the compression stroke, the compressed O-ring 40 is lowered in the state in which the O-ring 70 is in close contact with the piston 50, thereby introducing the air introduced into the cylinder 30. At this time, since the O-ring 70 maintains hermetically in close contact with the piston 50, the air passage 24 is blocked thereby, and air does not leak to the outside.

The present invention operates as described above, since the air smoothly flows into the cylinder 30 through the plurality of air passages 24 formed in the fixed rod 23 and the bolt 22 during the suction stroke, that is, the suction stroke in the present invention. Since air does not flow between the piston 50 and the cylinder 30 through the air passage 24 as in the prior art, the lubricant of the inner wall of the cylinder 30 is scratched up by the compression o-ring 40 when the air is introduced. It can be prevented from entering inside with the air flowing into the cylinder 30 while going up.

Therefore, the present invention can solve the problem of lubricating oil entering the inside with the air introduced into the cylinder 30, so that the lubricating oil of the inner wall of the cylinder 30 can be wiped clean and prevent it from drying out at the same time. And the life of the cylinder 30 can be extended.

In addition, the present invention is because the lubricant does not flow into the interior with the air flowing into the cylinder 30 as described above, that is, since the lubricant is not mixed in the solution of disinfectant, pesticide, nutrient, water, etc. Eliminate the problem that affects you.

In addition, the present invention, since the air flows smoothly into the cylinder 30 through the air passage 24 during the intake stroke, in fact, the air is maintained in the cylinder 30 so that the vacuum is not formed because the air is not compressed. Since the amount of compression increases and the amount of air compression increases in this way, the inconvenience of having to pump a lot as in the prior art can be eliminated.

As described above, the present invention can increase the amount of air compression during compression because the air flows smoothly into the cylinder through the air passage during the suction stroke of the compression rod, and also prevents the lubricant from drying out structurally and at the same time the compression O-ring And it is a very useful design that can extend the life of the cylinder, and prevent the lubricating oil from being mixed into the solution to adversely affect crops or plants.

Claims (3)

The handle 21 is provided to be inserted into the cylinder 30, the lower portion of the compression rod 20 protruding the bolt 22 is fitted with a piston 50 is fitted with a compression o-ring 40 is fastened to the nut 60 In the upper part of the bolt 22 to form a fixing rod 23 smaller than the outer diameter of the compression rod 20 and larger than the outer diameter of the bolt 22, the O-ring 70 and the piston 50 in the fixing rod 23 ) To assemble, but to secure the movement gap (G) to the piston (50) to move up and down on the fixing rod (23), the air reservoir perpendicular to the outside of the fixing rod (23) and bolt 22 Compression rod of the compressed automatic atomizer, characterized in that the furnace 24 is formed. The compression rod of claim 1, wherein the fixed rod (23) and the bolt (22) are formed with a plurality of air passages (24). The compressed rod of claim 1, wherein the air passage (24) is cut in a '+' shape.