KR20110018842A - Discharge implement of reservoir for portable pressurized sprayer - Google Patents

Abstract

PURPOSE: A discharge implement of a reservoir for a portable pressurized sprayer is provided to reduce the costs thereof in the aspect of fabrication and enable the efficient complete mixture and spraying of the components. CONSTITUTION: A discharge implement of a reservoir for a portable pressurized sprayer comprises: a mixing housing which is extended to a distal end in a vertical direction, wherein the distal end has a discharging hole for discharging components; at least one mixing element which is arranged in the mixing housing for mixing the components; a water outlet(12) and a water inlet(11); and a spraying sleeve which includes an inflow inlet for the inflow of the compressed spraying medium.

Description

Discharge mechanism of reservoir for portable pressurized sprayer {DISCHARGE IMPLEMENT OF RESERVOIR FOR PORTABLE PRESSURIZED SPRAYER}

TECHNICAL FIELD The present invention relates to a "draining mechanism of a portable pressurized nebulizer reservoir", and this "draining mechanism of a portable pressurized nebulizer reservoir" is characterized in that air is mixed or moistened with water discharged throughout the operation of a portable pressurized nebulizer. The moisture can be prevented from being removed and the internal state can be reliably kept dry. In this way, problems that adversely affect all the parts therein caused by the mixing of damped moisture and air and shorten the service life of the portable pressurized nebulizer can be completely solved.

Recently, in the conventional "portable pressurized nebulizers" disclosed in U.S. Pat.Nos. "Portable pressurized nebulizers" are almost similar in all construction. 1 to 3, a conventional conventional portable pressurized nebulizer is a water sprayer 1, a portable reservoir 2, a rechargeable battery 3 and a diaphragm compression pump. a compression pump (10), wherein the water sprayer (1) is a nozzle for flushing clean water for cleaning an object, and the water is a water intake hose from the portable reservoir (2). supplied via a hose (4), a diaphragm compression pump (10) and a water outtake hose (5). The portable reservoir 2, commonly referred to as a water tank, usually comprises a water replenishment inlet 21 for receiving water thereon and a recessed sole 23 in an L-shaped cross section, The recessed sole 23 is provided with a horizontal flat bottom and a pushed perpendicular vertical buttress to conveniently accommodate the rechargeable battery 3 and the diaphragm compression pump 10. A water outlet 20 is arranged on the pushed vertical support wall of the recessed sole 23. The rechargeable battery 3 provides power to the diaphragm compression pump 10 at 24 VDC and can be charged using a cigar-lighter power source receptacle of an automobile. The diaphragm compression pump 10 compresses the water from the portable reservoir 2 via the water suction hose 4 and propels the water into the water sprayer 1, wherein the diaphragm compression pump 10 receives water suction. A water inlet 11 connected to the hose 4 and a water outlet 12 connected to the water sprayer 1 are included. Therefore, the attractive function of the conventional portable pressurized nebulizer overcomes the limitation of water supply, so that if the portable reservoir 2 is filled with sufficient water W through the water replenishment inlet 21 in advance, Can be taken anywhere (as shown in FIG. 2). Once the conventional portable pressurized nebulizer is transferred to the cleaning operation site and powered on to drive the diaphragm compression pump 10, the water W of the portable reservoir 2 is sequentially discharged from the portable reservoir 2. Through the water outlet 20, the water suction hose 4 and the water inlet 11 of the diaphragm compression pump 10, it is sucked into the diaphragm compression pump 10 and compressed to become compressed water W ′. . The compressed water W 'is then sequentially discharged to the water sprayer 1 for cleaning operation via the water outlet 12 and the water discharge hose 5 of the diaphragm compression pump 10 (Fig. As shown in 3).

However, in the above-mentioned conventional portable pressurized nebulizer operation, when the water W stored in the portable reservoir 2 is exhausted, and the fresh water W is sufficiently replenished in the portable reservoir 2, the water suction hose 4 ), There is a problem of air remaining. Through the water intake hose 4, the water W flows from the water outlet 20 of the portable reservoir 2 to the water inlet 11 of the diaphragm compression pump 10 and thus into the water intake hose 4. The remaining air is mixed with water (W) to flow into the diaphragm compression pump (10), and the residual air flowing into the diaphragm compression pump (10) imposes an improper load on all parts of the diaphragm compression pump (10). In addition to the detrimental effect on stable compression, it can also cause malfunctions due to intermittent and unstable heavy impacts. For this reason, when air enters the diaphragm compression pump 10, since the improper load is applied to all the components of the diaphragm compression pump 10, the service life of the diaphragm compression pump 10 is shortened.

In other words, the problem of "residual air in water intake hose 4", which has always been present in all known conventional portable pressurized nebulizers, was not identified and solved until the present invention by the inventors. While dealing with the above-mentioned problem of removing the "remaining air in the water intake hose 4" when replenishing the portable reservoir 2 with water each time, the inventor of the present invention has conducted research and development for a long time through experimental tests. Has been actively carried out, and finally the present invention, an innovative solution, has been successfully achieved. With the success of the present invention, the inventor has filed a patent with the Chinese Patent Office under the registration number 200710195188.X (Publication CN101382128A). 4 and 5, the specific structure for the patent application of the Chinese Patent Office includes a cylindrical discharging mount 30 and a pneumatic hollow plunger 40, which is cylindrical The discharge mount 30 is a hollow cylinder and has a first cylindrical discharging arranged in fluid communication with each other in its lower and upper sections. a chamber 31 and a second cylindrical discharge chamber 32, the inner diameter of the first cylindrical discharge chamber 31 being larger than the inner diameter of the second cylindrical discharge chamber 32; The cylindrical discharge mount 30 also has a discharging vent 34 disposed at its central top toward the second cylindrical discharge chamber 32 and an air passage disposed at its bottom wall. Having an air passage 33, the first cylindrical discharge chamber 31 is in fluid communication with the water outlet 12 of the diaphragm compression pump 10. The hollow air plunger 40, which is a hollow piston such as a bucket, has a top opening end 41, a bottom flanged hatch end 42, and a built-in compression spring. (contained compressed spring) 43, side vents 44 and water tight sealing O-rings 45, wherein the opening end 41 has a second cylindrical discharge chamber. It is suitably embedded in a sliding manner in 32, and the flange sole of the flanged hatch end 42 is corrugated in a dial manner (not shown). The flange sole is suitably embedded in the first cylindrical discharge chamber 31 in a sliding manner with the air passage 33 of the cylindrical discharge mount 30 facing away. The compression spring 43 is suitably inserted into the hollow air plunger 40 through the top opening end 41. A side vent 44 is formed on the side wall of the hollow air plunger 40 near the flanged hatch end 42, so that if the hollow air plunger 40 is pushed completely to the rear, the side vent 44 is blocked. On the other hand, when the hollow air plunger 40 is fully pushed forward, the fluid in the first cylindrical discharge chamber 31 can flow through the side vent 44. And the sealing o-ring 45 is arranged around the peripheral of the hollow air plunger 40 while in contact with the top rim of the flanged hatch end 42 (in the enlarged part of FIG. 5). As shown).

 The operation modes in the patent application of the patent application No. 200710195188.X (Publication CN101382128A) to the above-mentioned Chinese Patent Office are shown in FIGS. 6 and 7. In the normal operating mode in which the air A is not mixed with the compressed water W ', the pressure of the compressed water W' at the water outlet 12 of the diaphragm compression pump 10 is reduced by the compression spring 43. Greater than the resilience force of), the flanged hatch end 42 of the hollow air plunger 40 is forced by the pressure of the water W 'compressed in the air passage 33 of the cylindrical discharge mount 30. Pushed back all the way. A portion of the compressed water W ′ in the water outlet 12 will flow into the first cylindrical discharge chamber 31 via the air passage 33, and the hollow air plunger 40 is a flanged hatch end ( 42. The sealing o-ring 45 on 42 is completely pushed into the second cylindrical discharge chamber 32 until it is in watertight contact with the distal inner end wall of the first cylindrical discharge chamber 31. And the compressed water W 'in the first cylindrical discharge chamber 31 cannot flow into the second cylindrical discharge chamber 32. And the compressed water W 'in the water outlet 12 can no longer enter the first cylindrical discharge chamber 31 through the air passage 33. Thus, all subsequent compressed water W 'flows normally through the water outlet 12 for legitimate purposes (as shown by solid arrows in FIG. 6). In an abnormal operating mode where air A is mixed with compressed water W ', the pressure of the compressed water W' at the water outlet 12 of the diaphragm compression pump 10 causes the compression spring 43 Of the flanged hatch end 42 of the hollow air plunger 40, the flanged hatch end 42 of the flanged hatch end 42 is ribbed by the elastic force of the compression spring 43. Fully pushed forward until it contacts the proximal inner end wall of the cylindrical discharge chamber 31, such that the side vent 44 on the side wall of the hollow air plunger 40 has a first cylindrical shape. Movement into the discharge chamber 31 allows fluid to flow therethrough. Therefore, the air A mixed in the compressed water W 'first passes through the air passage 33 and passes through the ribbed flange sole of the flanged hatch end 42 and then the first cylindrical discharge. It will enter the chamber 31. Secondly, the air A mixed in the compressed water W 'will enter the hollow air plunger 40 via the side vent 44 which is now moved into the first cylindrical discharge chamber 31. will be. And finally, the air A mixed in the compressed water W 'is sequentially passed through the opening end 41 of the hollow air plunger 40 and the discharge vent 34 of the cylindrical discharge mount 30. By being discharged to the outside of the diaphragm compression pump 10, it is possible to achieve the effect of discharging the air (A) mixed in the compressed water (W ') (as shown by the dashed arrow in Figure 7). The operating state after all air (A) mixed in the compressed water (W ') is discharged to the outside of the diaphragm compression pump 10, the normal state that the air (A) is not mixed with the compressed water (W') Will be resumed in mode, and the hollow air plunger 40 in the cylindrical discharge mount 30 is again forced to the rear second cylindrical discharge, as in the normal compression and discharge conditions (as shown in FIG. 6). Pushed into the chamber 32, the diaphragm compression pump 10 can resume normal compression and discharge operation.

After mass production through the molding process for the patent application of the registration number 200710195188.X (published number CN101382128A) to the Chinese patent office mentioned above, in order to obtain the expected satisfactory effect, the compressed water W ' Tests of the release effect were made. However, it has been found that the air A discharged out of the cylindrical discharge mount 30 of the diaphragm compression pump 10 has somewhat damp moisture. The damp moisture in the discharged air A not only has a detrimental effect on all the components in the portable pressurized nebulizer, but also creates a new problem that results in a bad effect of shortening the service life of the portable pressurized nebulizer. Therefore, the inventor of the present invention had to deal with the new problem of moist moisture in the air A to be discharged and to devise an additional and exhaustive solution of the present invention.

An object of the present invention is to provide a "discharge mechanism of a reservoir for a portable pressurized nebulizer" for solving the above-mentioned problems.

The "discharge mechanism of the portable pressurized nebulizer reservoir" for solving the above problems includes a discharging vent and a discharging hose, the discharge vent, the push for the recessed sole of the portable reservoir Penetrates through a vertical tucked buttress and has an outwardly exposed end; The discharge hose has one end opening connected to the exposed end of the discharge vent and another end opening connected to the cylindrical discharge mount of the diaphragm compression pump. If air is mixed with the compressed water, the air immediately enters the discharge hose with all the damp moisture in it and flows through the discharge vent into the portable reservoir, throughout the portable pressurized nebulizer operation, Moist moisture in the vented air can be completely removed.

According to the present invention, throughout the operation of a portable pressurized nebulizer, all the components therein, which can be completely removed from the damp moisture in the discharged air and the damp moisture does not remain, resulting from the damp moisture in the discharged air. It is possible to completely avoid the problems that adversely affect them and shorten the service life of the portable pressure sprayer.

1 is an exploded perspective view of a conventional portable pressure sprayer.
2 is an assembled perspective view of a conventional portable pressure sprayer.
3 is a cross-sectional view taken along line 3-3 of FIG.
4 is a partial perspective view of a conventional diaphragm compression pump for a portable pressurized nebulizer.
5 is a cross-sectional view taken along the line 5-5 of FIG.
6 is a view schematically showing a first operating state of a conventional diaphragm compression pump for a portable pressurized nebulizer.
7 is a view schematically showing a second operating state of a conventional diaphragm compression pump for a portable pressurized nebulizer.
8 is an exploded perspective view showing in cross section for a first preferred embodiment of the present invention.
9 is a cross-sectional view showing a schematic operating state of the first preferred embodiment of the present invention.
Fig. 10 is a cross-sectional view of the toothed barb periphery of the hollow fitting tube protruding in the first preferred embodiment of the present invention.
11 is an exploded perspective view showing in cross-section for a second preferred embodiment of the present invention.
Fig. 12 is a plan exploded view showing in cross section another discharge mechanism consisting of a discharge vent and a discharge hose in a second preferred embodiment of the present invention.
FIG. 13 is a planar assembly view, showing in cross section another discharge mechanism consisting of a discharge vent and a discharge hose in a second preferred embodiment of the present invention. FIG.

8 and 9, the "discharge mechanism of the reservoir for portable pressurized nebulizer" of the present invention is a recess in the reservoir 2 for accommodating the reservoir 2 and the diaphragm compression pump 10. and a diaphragm compression pump 10 having a water inlet 11 and a water outlet 12. The discharge implement includes a discharging vent 22 and a discharging hose 50, wherein the discharge vent 22 is a recess 23 of the reservoir 2. Extending through the wall of the discharge vent 22 and having a protruduing hollow fitting tube 24 extending from the wall into the recess 23. The outer diameter of the protruding hollow fitting tube 24 is such that the discharge hose 50 can be tightly mounted on the protruding hollow fitting tube 24. Slightly smaller (as shown in the enlarged portion of FIG. 9). The discharge hose 50 has a first opening 51 and a second opening 52, and the first opening 51 has a hollow fitting tube protruding from the discharge vent 22. 24, the second openings 52 are respectively connected to a cylindrical discharging mount 30 of the diaphragm compression pump 10 (as shown in FIG. 8).

In practical operation, if air A is mixed with the compressed water W ′ output from the diaphragm compression pump 10, firstly, the air A is the diaphragm compression pump 10. Will enter the discharge hose 50 via the discharge vent 34 in the cylindrical discharge mount 30. Secondly, the air A will pass through the discharge vent 22 of the reservoir 2 via the discharge hose 50. And finally, the air A will flow into the reservoir 2 with all the damp moisture in it. Thereby, throughout the operation of the portable pressurized nebulizer, the damp moisture in the discharged air A can be completely removed, thereby reliably preventing the damp moisture from remaining. Thus, the problems described above, which adversely affect all the parts in the interior caused by the damp moisture in the discharged air A and the problems of shortening the service life of the portable pressurized nebulizer, can be completely solved. have.

Referring to FIG. 10, on the protruding hollow fitting tube 24 of the discharge vent 22, a serrated barbed exterior surface 25 with a plurality of barbed ramps is provided. ), And the larger outer diameter of the peripheral of the serrated barbed outer surface 25 is approximately equal to the inner diameter of the discharge hose 50, so that the second opening 52 of the discharge hose 50 is It can be securely connected to the serrated barbed outer surface 25 of the discharge vent 22 without the possibility of being separated.

11 to 13, the connecting means for the discharge mechanism of the discharge vent 22 and the discharge hose 50 are further adapted, such that a T-shaped sectional flanged hollow tube is provided. 60, a coupling nut 70, and a watertight rubber annular washer 80 fitted in a ring shape. Here, the flanged hollow tube 60 of the T-shaped cross section extends through the wall of the recess 23, and in its front part is a toothed barbed periphery having a plurality of barbed inclined portions. 61 is further formed, and an outer male thread portion 62 in which a plurality of male threads are formed is further formed in the middle portion thereof, and a tubular neck 63 having a uniform outer diameter is further formed in the rear portion thereof. (As shown in FIG. 12). In the assembling process, firstly, the rubber annular washer 80 is sequentially passed through the serrated barb periphery 61 and the outer male threaded portion 62 to form a flanged hollow tube 60 having a T-shaped cross section. And fit on tubular neck 63 in contact with the top rim. Secondly, it is screwed with the coupling nut 70 to the outer male threaded portion 62 of the flanged hollow tube 60 of the T-shaped cross section. And finally, the first opening 51 of the discharge hose 50 is tightly coupled with the serrated barb periphery 61 of the flanged hollow tube 60 of the T-shaped cross section, so that it can be separated from each other. A tight connection effect can be obtained without this (as shown in the enlarged part of FIG. 13).

In conclusion, the significant problem due to the damp moisture in the discharged air, which existed in the conventional portable pressurized nebulizer, can be solved and eliminated by the innovative and simple device of the present invention. The present invention has novelty, progressiveness, and industrial applicability, which are patent licensing standards, and is therefore filed under patent law.

Claims (7)

A discharge implement of a reservoir for a portable pressurized sprayer, the discharge mechanism comprising a recess in the reservoir for accommodating the reservoir and the diaphragm compression pump. Wherein the diaphragm compression pump has a water inlet and a water outlet,
The discharge implement includes a discharging vent and a discharging hose, wherein the discharge vent extends through the wall of the recess, and the discharge hose is connected to the discharge vent. Having a first end opening and a second end opening connected to a cylindrical discharging mount at the water outlet of the diaphragm compression pump,
Thus, the discharge hose provides a passage for allowing the air passing through the cylindrical discharge mount of the water outlet to be discharged back to the reservoir through the discharge vent.
The method of claim 1,
The first end of the discharge hose is connected to the discharge vent by a protruduing hollow fitting tube extending from the wall to the recess, wherein the discharge hose is connected to the protruding hollow fitting. Wherein the outer diameter of the protruding hollow fitting tube is slightly smaller than the inner diameter of the discharge hose so that it can be tightly mounted to the tube.
The method of claim 2,
The protruding hollow fitting tube has a serrated barbed exterior surface with a plurality of barbed ramps and the serrated barbed outer surface peripheral. A larger outer diameter of the discharge hose is substantially equal to the inner diameter of the discharge hose, so that the discharge hose is prevented from being separated from the protruding hollow fitting tube by the barbed inclined portions. Instrument.
The method of claim 1,
The first end of the discharge hose is connected to the discharge vent by a T-shaped sectional flanged hollow tube extending through the wall of the recess, the hollow The tube of claim 1, characterized in that it comprises a peripheral surface (peripheral surface) to which the discharge hose is connected.
The method of claim 4, wherein
The hollow tube is threaded on the outside and further comprises a coupling nut and an annular watertight washer, between the flange of the T-shaped portion and the wall. A discharge mechanism of a reservoir for a portable pressure sprayer, characterized in that the discharge hose can be fixed to the hollow tube by sandwiching a washer and screwing the coupling nut onto the hollow tube.
The method of claim 5,
In the front part of the hollow tube there is a serrated barbed peripheral surface with a plurality of barbed ramps for retaining the discharge hose over the hollow tube, the middle part of the hollow tube An external thread is formed to receive the nut, and a tubular neck of uniform outer diameter is formed in the rear portion of the hollow tube, which extends from the intermediate portion to the flange. A discharge mechanism of a reservoir for a portable pressurized nebulizer, which is provided.
The method of claim 4, wherein
The hollow tube has a serrated barbed perimeter surface with a plurality of barbed ramps for retaining the discharge hose over the hollow tube. Discharge mechanism

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