KR101172184B1 - Air discharge implement for a portable pressurized sprayer - Google Patents

Abstract

The present invention provides an air discharge mechanism for a portable pressurized nebulizer, comprising a cylindrical main body, an external hood jacket, a conical moving plug and a compression spring that are discharge ducts. The main body, which is a hollow discharge duct, comprises a cylindrical bore, a cylindrical discharging mount containing a conical moving plug, and an air passage interposed between the hollow discharge chamber and the cylindrical bore. The outer hood jacket is a hollow holder adapted to contain a compression spring. The conical moving plug includes a top planar base and a flat planar base with a number of footing legs, with a water flow gap between the flat sole and the air passage of the cylindrical bore. gap) is formed. When the present invention is properly connected to the water discharge hose of the portable pressurized sprayer, even if there is no air or air is mixed in the compressed water, the air discharge effect can be completely achieved.

Description

Air discharge mechanism for portable pressurized sprayer {AIR DISCHARGE IMPLEMENT FOR A PORTABLE PRESSURIZED SPRAYER}

The present invention relates to an "air discharge mechanism for a portable pressurized nebulizer", and in particular, it is possible to completely solve and eliminate the long-term problem with the air entrained in the compressed water, thereby reducing the output water pressure of the portable pressurized nebulizer It is directed to an air discharge mechanism that can be universally inserted into the water discharge hose of any existing portable pressurized nebulizer so that the problem of breaking and instability can be avoided as a whole.

Recently, in the conventional "portable pressurized nebulizers" disclosed in U.S. Pat. Nos. 7118050 and 5303866, and in Taiwan Patent No. 1253421, et al. Almost similar. 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 pump (10), wherein the water sprayer (1) is a nozzle for flushing clean water for cleaning an object, the water being a water intake hose (4) from a portable reservoir (2) Supplied via 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 supplement inlet 21 for receiving water thereon and a recessed flat base 22 in an L-shaped cross section, the recess The flat base 22 is comprised of a horizontal flat bottom and a pushed perpendicular vertical buttress to accommodate the rechargeable battery 3 and the diaphragm compression pump 10 conveniently. A water outlet 20 is disposed on the pushed vertical support wall of the recessed flat base 22; 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 and propels water from the portable reservoir 2 through the water suction hose 4 to the water sprayer 1, and the diaphragm compression pump 10 is a water suction hose ( A water inlet 11 connected to 4) and a water outlet 12 connected to the water sprayer 1. Therefore, the attractive function of the conventional portable pressurized nebulizer overcomes the limitations on the water supply, so that the portable reservoir 2 has sufficient water (W) through the water supplement inlet 21 (as shown in FIG. 2) in advance. If filled, it can be taken anywhere outdoors for cleaning. 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 ′. ; Then, the compressed water W 'is sequentially passed through the water outlet 12 and the water discharge hose 5 of the diaphragm compression pump 10 (as shown in FIG. 3), and the water for the washing operation. It is discharged to the nebulizer 1.

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 to the portable reservoir 2, the "water suction hose ( 4) has a problem of "remaining air." 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 entrained in water W and flows into the diaphragm compression pump 10. Residual air flowing into the diaphragm compression pump 10 imposes an improper load on all parts of the diaphragm compression pump 10, which not only has a detrimental effect on stable compression, but also the water outlet of the water outlet 12. It may cause malfunction due to intermittent and unstable heavy shock at pressure. As a result, when air enters the diaphragm compression pump, the service life of the diaphragm compression pump 10 is shortened because an improper load is applied to all parts of the diaphragm compression pump.

For this reason, the inventor of the present invention has been experimenting for a long time while dealing with the problem of solving the above-mentioned problem of "remaining air in the water intake hose 4" when replenishing the water in the portable reservoir 2 each time. We have been actively conducting research and development through testing. Finally, an innovative solution was successfully achieved and filed a patent in Taiwan under registration number 096142614 (published number 200912139). 4 and 5, a specific structure for patent application to the Chinese Patent Office includes a cylindrical discharging mount 30 and a pneumatic hollow plunger 40, wherein the cylindrical discharge The mount 30 is a hollow cylinder and has a first cylindrical discharging chamber 31 arranged in fluid communication with each other in its lower and upper sections. And a second cylindrical discharge chamber 32, wherein the inner diameter of the first cylindrical discharge chamber 31 is larger than the inner diameter of the second cylindrical discharge chamber 32, and the cylindrical discharge mount 30 is at its center. The first cylindrical having a discharging vent 34 disposed towards the second cylindrical discharge chamber 32 and an air passage 33 disposed at the bottom wall thereof. The discharge chamber 31 Diaphragm is capable of the water outlet 12 in fluid communication with the compression pump 10, and; 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, a backing compression spring backing compression spring (43), side vents (44) and water tight sealing o-rings (45), said opening end (41) having a second cylindrical discharge chamber ( Appropriately embedded in a sliding manner in 32, the flanged hatch end 42 has a first cylindrical discharge with its flat flange sole facing the air passage 33 of the cylindrical discharge mount 30. It is suitably embedded in the chamber 31 in a sliding manner, and the compression spring 43 is fitted snugly into the hollow air plunger 40 opposite the opening end 41 and has a flanged hatch end. Side vents 44 are formed on the sidewalls of the hollow air plunger 40 near 42. If the hollow air plunger 40 is pushed completely to the rear, the side vent 44 is blocked, while if the hollow air plunger 40 is pushed completely to the front, the first cylindrical discharge chamber ( Fluid in 31 can pass through the side vent 44. The sealing o-ring 45, on the other hand, is in contact with the top rim of the flanged hatch end 42 (as shown in the enlarged portion of FIG. 5) while the periphery of the hollow air plunger 40 ( peripheral).

Operation modes in the above-described patent application 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 resilient 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. And a portion of the compressed water W ′ in the water outlet 12 will flow through the air passage 33 into the first cylindrical discharge chamber 31 and into the hollow air plunger 40. ) The second cylindrical until the sealing o-ring 45 on the flanged hatch end 42 is in watertight contact with the distal inner end wall of the first cylindrical discharge chamber 31. Completely pushed into the discharge chamber 32, and the compressed water W 'in the first cylindrical discharge chamber 31 is transferred into the second cylindrical discharge chamber 32. It is impossible to flow, so that the compressed water W 'in the water outlet 12 can no longer flow into the first cylindrical discharge chamber 31 through the air passage 33. Thus, all subsequent compressed water W 'will flow normally through the water outlet 12 (as shown by the solid arrows in FIG. 6) for proper purposes. On the other hand, in an abnormal operation mode in which 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 is reduced by the compression spring 43. The flanged hatch end 42 of the hollow air plunger 40 has a flat flange of the flanged hatch end 42 which is ribbed by the elastic force of the compression spring 43, which is less than the elastic force of The sole is pushed forward fully until it comes into contact with the inner side inner end wall of the first cylindrical discharge chamber 31 such that the side vent 44 on the side wall of the hollow air plunger 40 has a first cylindrical discharge chamber. It moves into (31) so that fluid can flow. Thus, the air A mixed in the compressed water W 'first passes through the air passage 33 and passes through the flat flanged sole of the flanged hatch end 42 and then the first cylindrical. Will flow into the discharge 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 that the air (A) mixed in the compressed water (W ') (as shown by the dashed arrow in Figure 7) is discharged. 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 second rearward, as in the normal compression and discharge position (as shown in FIG. 6). Pushed into the cylindrical discharge chamber 32, the diaphragm compression pump 10 can resume normal compression and discharge operation.

Test for the effect of the discharge of air (A) mixed in the compressed water (W ') to obtain the expected satisfactory effect after mass production through the molding process for the patent application of registration number 096142614 in Taiwan mentioned above. Was done. However, other shortcomings have been found in the test in the situation as shown in FIG. Prior to the start of operation of the diaphragm compression pump 10, the flanged hatch end 42 of the hollow air plunger 40 is caused by the elasticity of the backing compression spring 43 so that the air passage 33 of the cylindrical discharge mount 30 is reduced. Will be completely blocked. At that moment, if there is any residual air A in the water intake hose 4, the compressed water W ′ of the water outlet 12 is air A when the diaphragm compression pump 10 is started. And the water pressure of the compressed water (W ') will be kept lower than the elasticity of the backing compression spring (43) by reducing the water pressure of the compressed water (W'). Thereby, the flanged hatch end 42 of the hollow air plunger 40 is mounted with a cylindrical discharge mount under elasticity of the backup compression spring 43 (such as the arrow heads of the phantom line shown in the air passage 33 in FIG. 8). Since the air passage 33 of 30 will be kept completely blocked, the air A mixed in the compressed water W 'will never be discharged smoothly. If this situation is not improved, there will be detrimental consequences which will adversely affect the air bleeding of the interior, which will be a new problem for portable pressurized nebulizers. Therefore, the inventor of the present invention had to solve this new problem and came up with a new and complete solution according to the present invention.

The main object of the present invention is an "air exhaust mechanism for a portable pressurized nebulizer" comprising a cylindrical main body, an external hood jacket, a conical moving plug and a compression spring which are discharge ducts. To provide. Here, the main body, which is an exhaust duct of a hollow tube, has a cylindrical bore, a cylindrical discharging mount disposed on its wall to contain a conical moving plug, and a hollow discharging chamber. ) And an air passage interposed between the cylindrical bore; The outer hood jacket is an inverted hollow bucket-shaped holder for covering a cylindrical spring mount in the main body, which is an exhaust duct, as well as for embedding a compression spring therein; The conical moving plug comprises a top cone and a flat planar base having a plurality of footing legs of the same length, the main body being the flat sole and the discharge duct of the conical moving plug. A water flow gap is formed between the air passages of the cylindrical bore of the same height as the height of the putting leg. When properly connected to the water discharge hose of a portable pressure sprayer, the "air discharge mechanism for portable pressure sprayer" of the present invention incorporates air into the compressed water so that the total water pressure is less than the elasticity of the compression spring, even the diaphragm Even in the state where the compression pump is started, the present invention still has an air bleeding capacity that satisfies the expected effect. Thus, even if there is no air or air is mixed in the compressed water, the present invention can achieve the air releasing effect completely.

In order to install the "air venting mechanism for portable pressurized nebulizer" of the present invention on an existing portable pressurized nebulizer, the water discharge hose of the existing portable pressurized nebulizer is cut into two separate pieces at any suitable position and discharged. This is simple and easy since each open end in the cylindrical bore of the main body, which is a duct, needs to be inserted into each corresponding end of each of the separate water discharge hoses described above. Another object of the present invention is to provide air discharge for a portable pressurized nebulizer, which is characterized by a simple and easy connection means for installing the "air venting device for a portable pressurized nebulizer" of the present invention on an existing portable pressurized nebulizer as described above. Mechanism ". Thus, any existing portable pressurized nebulizer without air vents can be used as appropriate without paying additional costs to purchase new products with air vents to replace the existing ones. Thus, the consumer can solve the air emission problem at a minimum cost.

When properly connected to the water discharge hose of a portable pressure sprayer, the "air discharge mechanism for portable pressure sprayer" of the present invention incorporates air into the compressed water so that the total water pressure is less than the elasticity of the compression spring, even the diaphragm Even in the state where the compression pump is started, the present invention still has an air bleeding capacity that satisfies the expected effect. Thus, even if there is no air or air is mixed in the compressed water, the present invention can achieve the air releasing effect completely.

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. 2;
4 is a partial perspective view showing a diaphragm compression pump of a conventional portable pressure sprayer;
5 is a cross-sectional view taken along line 5-5 of FIG. 4;
Figure 6 is a schematic first operating cross-sectional view showing the air discharge action of the diaphragm compression pump of a conventional portable pressurized nebulizer,
Figure 7 is a schematic second operation cross-sectional view showing the air discharge action of the diaphragm compression pump of the conventional portable pressurized nebulizer,
FIG. 8 is a schematic third operation cross sectional view showing an air bleeding action of a diaphragm compression pump of a conventional portable pressurized nebulizer; FIG.
9 is a perspective view showing an air discharge mechanism installed on the portable pressurized nebulizer of the present invention;
10 is an exploded perspective view according to a first preferred embodiment of the present invention;
11 is an assembled perspective view according to a first preferred embodiment of the present invention;
12 is a sectional view taken along line 12-12 of FIG. 11;
13 is a schematic first sectional view of operation according to the first preferred embodiment of the present invention;
14 is a schematic cross-sectional view of a second operation according to the first preferred embodiment of the present invention;
Fig. 15 is a third schematic cross sectional view of operation according to the first preferred embodiment of the present invention;
Fig. 16 is a bottom view showing a modified conical moving plug according to the first preferred embodiment of the present invention.
FIG. 17 is a sectional view taken along line 17-17 of FIG. 16;
18 is a cross-sectional view taken along line 18-18 of FIG. 16;
Fig. 19 is a first schematic sectional view showing a modified conical moving plug according to a first preferred embodiment of the present invention;
Fig. 20 is a schematic second operational cross sectional view showing a modified conical moving plug according to the first preferred embodiment of the present invention;
Fig. 21 is a sectional view showing a modified cylindrical main body according to the first preferred embodiment of the present invention;
Fig. 22 is a sectional view showing a modified outer hood jacket according to the first preferred embodiment of the present invention;
Fig. 23 is a schematic sectional view showing a modified outer hood jacket according to the first preferred embodiment of the present invention;
24 is an exploded perspective view showing a modified conical moving plug and an additional annular washer according to a second preferred embodiment of the present invention;
Figure 25 is a first schematic cross sectional view showing a modified conical moving plug and additional annular washer according to a second preferred embodiment of the present invention;
FIG. 26 is a second cross sectional view showing a modified conical moving plug and additional annular washer according to a second preferred embodiment of the present invention; FIG.
Figure 27 is an exploded perspective view showing a modified outer hood jacket and a modified cylindrical main body according to the third preferred embodiment of the present invention;
Figure 28 is a first schematic cross sectional view showing a modified outer hood jacket and a modified cylindrical main body according to a third preferred embodiment of the present invention, and
Figure 29 is a second schematic cross-sectional view showing a modified outer hood jacket and a modified cylindrical main body according to a third preferred embodiment of the present invention.

As shown in Figures 9-13, the "air vent mechanism for a portable pressurized nebulizer" of the first exemplary preferred embodiment of the present invention is a cylindrical main body 50, an external hood jacket. 60, a conical moving plug 90 and a compression spring 80.

The main body 50 is a hollow tube manufactured by the integral injection molding method with a bore of approximately the same outer diameter with respect to the water outtake hose 5 of the portable pressure sprayer. As a cylindrical bore 51 for the flow of compressed water W 'therein, a cylindrical discharge mount with a male external thread 53 disposed vertically on its wall. (cylindrical discharging mount) 52, a central hollow internal discharge chamber 54 with a bottom side 55 of a solid ring, and a hollow discharge chamber 54 54 and an air passage 56 interposed between the cylindrical bore 51 and allowing water to communicate with each other.

The outer hood jacket 60 is an inverted hollow bucket-shaped holder covering the top of the cylindrical discharge mount 52 of the main body 50, sequentially from the top of the center inner portion to the bottom. Discharging vent 61, airflow passage 62, intake chamber 63 with the upper side of the solid ring, and internal female thread 64. And the air vent passage 62 and the suction chamber 63, as well as the discharge vent 61 and the air flow passage 62, the bore of the suction chamber 63 It is larger than the bore of the airflow passage 62, and the bore of the airflow passage 62 is larger than the bore of the discharge vent 61.

The conical moving plug 90 is made of a flexible resilient material situated in the hollow discharge chamber 54 of the main body 50, so that the top cone 92 and a plurality of footing legs of the same length ( a planar base 91 with footing legs 93.

The compression spring 80 inserted in the air flow passage 62 of the outer hood jacket 60 has a conical moving plug 90 such that its inner diameter is smaller than the outer diameter of the upper conical body 92 of the conical moving plug 90. It is formed with the bottom thereof in contact with the upper cone body (92).

As shown in Figs. 10 to 12, the assembly process of the "air discharge mechanism for the portable pressurized nebulizer" of the first exemplary preferred embodiment of the present invention is very simple and easy. First, in order to insert the conical moving plug 90 into the hollow discharge chamber 54 of the cylindrical discharge mount 52, the flat sole 91 of the conical moving plug 90 is mounted to the cylindrical discharge mount of the main body 50 ( In alignment with 52, attaching the footing legs 93 of the moving plug 90 to the bottom side 55 of the hollow discharge chamber 54 in a firm manner; Secondly, the compression spring 80 is inserted into the airflow passage 62 of the outer hood jacket 60 so that the bottom coil of the bottommost side of the compression spring 80 is the upper conical body 92 of the movable plug 90. Firmly attached to the; Finally, cover the outer hood jacket 60 slightly over the cylindrical discharge mount 52 of the main body 50, and then the internal female thread (as shown in FIGS. 11 and 12) to complete the assembly process. Tighten 64 to engage the external male portion 53 of the cylindrical discharge mount (52). Thereby, a water flow gap having a height equal to that of the putting leg 93 is formed by the air passage 56 of the cylindrical bore 51 of the main body 50 (as shown in FIG. 12) and It is formed between the flat sole 91 of the conical moving plug 90.

The installation, use and operation of the "air releasing mechanism for a portable pressurized nebulizer" of the first exemplary preferred embodiment of the present invention are shown in Figures 9 and 12-15. Firstly, the water discharge hose 5 is cut into the water discharge hose 5a piece and the other water discharge hose 5b piece (as shown in FIG. 9) at any suitable position: second, the main body ( Each opening end of the cylindrical bore 51 of 50 is inserted into each corresponding end of the water discharge hose 5a and the water discharge hose 5b and onto the portable pressure sprayer (as shown in FIG. 13). Complete the installation of "Air venting device for portable pressurized sprayer". In the normal mode in which air A is not incorporated into 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 80. The compressed water W 'flowing from the water outlet 12 of the diaphragm compression pump 10 through the water discharge hose 5b is greater than the elastic force of the cylindrical bore 51 of the main body 50. It will flow through the air passage 56 of the hollow discharge chamber 54 of the cylindrical discharge mount 52, the conical moving plug (W ') by the compressed water (W') to win the elastic force of the compression spring (80). 90 is pushed upwards, so that its upper cone 92 is completely pushed up into the airflow passage 62 of the outer hood jacket 60, and the movable plug 90 with flexible and elastic material properties. ) Has an anti-leakage effect on the outer hood jacket (60), which has a hard material characteristic. Since the contact, on the upper side of the suction chamber 63, the solid ring is attached in a sealed state in a watertight manner; As a result, all the compressed water W 'of the hollow discharge chamber 54 cannot flow into the airflow passage 62 of the outer hood jacket 60, as indicated by the solid arrows in the enlarged view shown in FIG. Sequentially flows into the water sprayer 1 through the cylindrical bore 51 of the main body 50 and the water discharge hose 5a. This mode of operation is indicative of the steady state of the diaphragm compression pump 10 and the portable pressurized nebulizer 1.

In the abnormal mode in which air A is incorporated into 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 80. The conical moving plug 90 is pushed downward by the resilient force of the compression spring 80, which becomes smaller than the resilient force and overcomes the resulting water pressure of the compressed water W 'into which air A is incorporated. Its upper cone 92 is separated at the upper side of the solid ring of the suction chamber 63 while a water flow gap is formed between the upper cone 92 and the upper side of the solid ring of the suction chamber 63. do. Thereby, the air A entrained in the compressed water W 'flowing from the water outlet 12 of the diaphragm compression pump 10 through the water discharge hose 5b is, firstly, the cylindrical shape of the main body 50. It will flow through the air passage 56 of the bore 51 into the hollow discharge chamber 54 of the cylindrical discharge mount 52, and subsequently the upper face of the upper cone body 92 of the conical moving plug 90. And flow through the plurality of gaps between the coils of the compression spring 80 to the air flow passage 62, and finally discharged to the outside of the outer hood jacket 60 through the discharge vent 61 to obtain the air discharge effect. (As indicated by dashed arrows in FIGS. 14 and 14). After all the air entrained in the compressed water W 'at the water outlet 12 of the diaphragm compression pump 10 is discharged outside the outer hood jacket 60, the pressure of the compressed water W' Larger than the resilient force of the compression spring 80, the conical moving plug 90 is pushed upwards again by compressed water W ', which overcomes the resilient force of the compression spring 80, thereby The upper conical body 92 is pushed completely into the airflow passage 62 of the outer hood jacket 60 and attached in a watertight manner on the upper side of the solid ring of the suction chamber 63; Thus, the diaphragm compression pump 10 and the portable pressurized nebulizer 1 are resumed in normal operation (as shown in FIG. 13).

Before starting the diaphragm compression pump 10, the flat sole 91 of the conical moving plug 90 is operated because the conical moving plug 90 is actuated by the elasticity of the compression spring 80 (as shown in FIG. 12). ) And the air flow gap 56 of the cylindrical bore 51 of the main body 50 is formed with a water flow gap equal to the height of the putting leg 93. At this time, when the air A is mixed in the compressed water W 'and the diaphragm compression pump 10 is started while the pressure of the entire water is lower than the elasticity of the compression spring 80, the compressed water W' Air (A) entrained therein first flows into the hollow discharge chamber (54) through the water flow gap between the flat sole (91) of the conical moving plug (90) and the air passage (56) of the cylindrical bore (51). And then sequentially into the airflow passage 62 through a plurality of gaps between the upper surface of the upper cone body 92 of the conical moving plug 90 and the coils of the compression spring 80, and finally Since the air A is discharged (in the direction indicated by the dotted arrow in Fig. 15) outside the outer hood jacket 60 through the discharge vent 61, the air discharge effect is obtained. The air venting mechanism for a portable pressurized nebulizer still has an air venting effect. Thus, even when there is no air A in the compressed water W 'or when air A is incorporated, the "air discharge mechanism for the portable pressurized nebulizer" of the present invention can achieve a full air discharge effect. .

16-20, there is shown a modified conical moving plug 900 of a second exemplary preferred embodiment of the present invention, in which the conical moving plug 900 is an upper conical body 902 and And a flat sole 901 having a plurality of grooves 903 intersected. In the case where air A is incorporated in the compressed water W ', the above air A incorporated in the compressed water W' firstly blows out through the grooves 903 of the flat sole 901. Airflow passage 62 through the plurality of gaps between the upper surface of the upper conical body 902 of the conical moving plug 900 and the coils of the compression spring 80 in turn. ) And finally, the air A is discharged to the outside of the outer hood jacket 60 through the discharge vent 61 to obtain an air discharge effect (as shown in FIG. 19). The pressure of the compressed water W 'at the water outlet 12 of the diaphragm compression pump 10 is determined by the compression spring 80 after all the air A entrained therein is discharged outside the outer hood jacket 60. Greater than the resilient force of), the conical moving plug 900 is pushed upwards by compressed water (W '), which again overcomes the resilient force of the compression spring (80), thereby increasing its upper cone ( 902 is pushed up completely into the airflow passage 62 of the outer hood jacket 60 and attached in a watertight manner on the upper side of the solid ring of the suction chamber 63. Thus, the diaphragm compression pump 10 and the portable pressurized nebulizer 1 are resumed in normal operation (as shown in FIG. 20).

Referring to Figure 21, there is shown a modified cylindrical main body 50 of a third exemplary preferred embodiment of the present invention, wherein the periphery of each end of the cylindrical main body 50 is each of a continuous and parallel arrangement. It has been adapted to a number of chamfered ridges 57 with a light fluke, wherein the larger diameter of the chamfered ridges 57 described above is the water discharge hose 5a, 5b. Approximately coincides with the bore of; Thus, when each water discharge hose 5a, 5b is fitted in the form of a sleeve over the periphery of each corresponding end of the cylindrical main body 50, the chamfered ridges 57 enhance the coupling effect, thereby separating You get a tight, firm coupling that is unlikely to be.

Referring to Figures 22 and 23, there is shown a modified outer hood jacket 600 of a fourth exemplary preferred embodiment of the present invention, in which the outer hood jacket 600 is disposed at its top periphery and is at right angles. The discharge vent 601 and the air vent passage 602 projecting at right angles are orthogonal to each other and water may communicate with each other. Thus, the air A entrained in the compressed water W 'does not directly impact on the other parts in the portable pressurized nebulizer as in the conventional manner described above, but rather (as shown in Fig. 23). It may be bypassed via an outlet vent 601 projecting at a right angle.

24 to 26, an annular washer 70 and a modified conical moving plug 910 are added in the suction chamber 63 of the outer hood jacket 60 of the fifth exemplary preferred embodiment of the present invention. In this embodiment, the conical moving plug 910 is made of a rigid plastic material by an integral injection molding method, and the annular washer 70 is made of an elastic rubber material, the bore of which is a compression spring ( It is larger than the outer diameter of 80 and its outer diameter is slightly larger than the bore of the suction chamber 63, so that the annular washer 70 can be press-fitted so that there is no possibility of detachment from the suction chamber 63. If air A is entrained in the compressed water W ', air A entrained in the compressed water W' is first put under the flat sole 911 of the conical moving plug 910. Flows through the water flow gaps between the legs 913 into the hollow discharge chamber 54, after which the upper surface of the upper conical body 912 of the conical moving plug 910 and the coils of the compression spring 80 It will flow through the plurality of gaps to the air flow passage 62, and finally air A is discharged to the outside of the outer hood jacket 60 through the exhaust vent 61 to obtain an air discharge effect (Fig. As shown at 25). The pressure of the compressed water W 'at the water outlet 12 of the diaphragm compression pump 10 is resilient to the compression spring 80 after all the air entrained therein is discharged outside the outer hood jacket 60. Larger than the force, the conical moving plug 910 is pushed upwards by compressed water W ', again overcoming the resilient force of the compression spring 80, thereby causing its upper cone 912 to be annular washer It is completely pushed up into the airflow passage 62 of the outer hood jacket 60 together with the 70 and is sealedly attached on the upper side of the solid ring of the suction chamber 63; Thus, the diaphragm compression pump 10 and the portable pressurized nebulizer 1 are resumed in normal operation (as shown in FIG. 26).

Referring to Figures 27-29, there is shown a modified outer hood jacket 610 and a modified main body 510 of a sixth exemplary preferred embodiment of the present invention, in which the outer hood jacket 610 is shown. It comprises an exhaust vent 611, an airflow passage 612 and an external male portion 614 formed on the periphery of the hollow discharge chamber 613 and its lower section sequentially from the top to the bottom of its central inner portion, the vent vent 611 and the air flow passage 612 as well as the air flow passage 612 and the hollow discharge chamber 613 are each in fluid communication with each other, the bore of the hollow discharge chamber 613 is a conical moving plug ( 90 is larger than the bore of the airflow passage 612 and the bore of the airflow passage 612 is larger than the bore of the exhaust vent 611; The cylindrical main body 510 sequentially has a suction chamber having a cylindrical discharge mount 512 and an internal female thread 514 formed therein to screw into a corresponding external male thread 614 on the outer hood jacket 610. 513. 28 and 29 show the operation of the air exhaust system. If air A is entrained in the compressed water W ', the air A entrained in the compressed water W' is first below the flat sole 91 of the conical moving plug 90. Flows through the water flow gaps between the putting legs 93 into the hollow discharge chamber 613 of the outer hood jacket 610, after which the upper face of the upper cone body 92 of the conical moving plug 90 and A plurality of gaps between the coils of the compression spring 80 flows to the air flow passage 612, and finally, the air A is discharged to the outside of the outer hood jacket 610 through the discharge vent 611 to discharge the air. Emission effect will be obtained (as shown in FIG. 28). After all the air A entrained in the compressed water W 'at the water outlet 12 of the diaphragm compression pump 10 is discharged outside the outer hood jacket 610, the pressure of the water is reduced by the compression spring 80. Larger than the resilient force of), the conical moving plug 90 is pushed upward again by the compressed water W ', which overcomes the resilient force of the compression spring 80, thereby conical moving plug ( The upper cone 92 of 90 is pushed up completely into the airflow passage 612 of the outer hood jacket 610 to seal and block the hollow discharge chamber 613 in a watertight manner. Thus, the diaphragm compression pump 10 and the portable pressurized nebulizer 1 are resumed in normal operation (as shown in FIG. 29).

In conclusion of the present publication, by virtue of its simple structure, the "air discharge mechanism for portable pressurized nebulizer" of the present invention completely solves the air discharge problem existing in conventional portable pressurized nebulizers due to the air entrained in the compressed water. By solving and eliminating, the present invention has truly practical industrial applicability and meets the criteria of patentability.

Claims (9)

Main body;
External hood jackets;
Conical moving plugs; And
Includes a compression spring,
The main body is a hollow tube comprising a cylindrical bore and a cylindrical discharging mount, wherein the discharge mount is a hollow discharge chamber inside the center and the cylindrical bore and hollow An air passage interposed between the discharge chambers includes:
The outer hood jacket is an inverted hollow bucket-shaped holder fixed to the cylindrical discharge mount of the main body, the outer hood jacket having a discharging vent, an airflow passage. And an intake chamber, wherein the air vent passage and the suction chamber as well as the discharge vent and the air passage are in fluid communication, respectively, and the diameter of the suction chamber is larger than the diameter of the air flow passage. The diameter of the air flow passage is greater than the diameter of the vent vent:
The conical moving plug is movably disposed in the hollow discharge chamber of the main body, the conical moving plug comprising a top cone and a planer base, wherein the flat sole includes the flat sole. There is either a plurality of footing legs or a plurality of grooves protruding from it;
The compression spring is disposed in the airflow passage of the outer hood jacket such that the lower portion of the compression spring contacts the upper cone of the conical moving plug, and the inner diameter of the compression spring is smaller than the outer diameter of the upper cone. A compression spring will urge the plurality of footing legs of the conical moving plug against the hollow tube,
When the flat sole of the conical moving plug is pressed against the hollow tube, air in the cylindrical bore of the hollow tube passes through the air passage and the plurality of putting legs or through the intersecting grooves, so that the cylindrical Flows into the hollow discharge chamber of the discharge mount, the air flows from the hollow discharge chamber through the suction chamber, the airflow passage and the discharge vent of the outer hood jacket,
As the pressure of the water flowing through the cylindrical bore of the hollow discharge chamber increases, the conical moving plug moves away from the hollow tube such that additional air flows through the air passage into the hollow discharge chamber, and the hollow From the discharge chamber through the suction chamber, the air flow passage and the discharge vent,
As the pressure of the water flowing through the cylindrical bore of the hollow discharge chamber further increases, the conical moving plug seals the air flow passage between the air discharge passage of the hollow discharge chamber and the outer hood jacket.
Air venting device for portable pressurized sprayer.
The method of claim 1,
And the flat sole comprises a plurality of footing legs.
The method of claim 1,
And the flat sole comprises a plurality of grooves.
The method of claim 1,
The discharge vent is a discharge vent projecting at right angles, disposed on an upper side of the outer hood jacket, the discharge vent projecting at right angles and the air flow passages are perpendicular to each other and in fluid communication with each other, air for a portable pressurized nebulizer Exhaust mechanism.
The method of claim 1,
And the conical moving plug is made of a flexible elastic material.
The method of claim 1,
An annular washer is additionally disposed in the suction chamber of the outer hood jacket, the conical moving plug is made of hard plastic material and the annular washer is made of elastic rubber material, the bore of the annular washer Is larger than the outer diameter of the compression spring, and the outer diameter of the annular washer is slightly larger than the diameter of the suction chamber.
The method of claim 1,
And the outer hood jacket is made of an injection molded material.
The method of claim 1,
The outer hood jacket includes a female internal thread in the lower portion, the cylindrical discharge mount includes a male external thread in the periphery of the cylindrical discharge mount, and the outer hood jacket includes An air exhaust mechanism for a portable pressurized nebulizer screwed onto the exhaust mount.
The method of claim 1,
The outer hood jacket includes an outer male portion at a lower portion, and the cylindrical discharge mount includes an inner female portion, wherein the outer male portion of the outer hood jacket is screwed into the inner female thread portion. .

Images