RU2336925C2 - Filter-insert for reservoir of spray gun - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention is intended for liquid filtration and supply into spraying accessories. Unit of liquid supply includes reservoir that is connected to spaying accessory of spray gun type, filter in the form of extended tubular shell open at its one end and closed at the other end. At the open end support collar is provided, which is inserted into filling opening of reservoir and fixes the open end so that filter casing comes off the opening in reservoir in the process of liquid refilling, at that tubular casing of filter is characterised by rigidity sufficient for preservation of its extended tubular shape, and its surface area and volume after its installation in reservoir makes it possible to refill liquid into reservoir in the process of operation for creation of filtered liquid inventory in reservoir, which might be supplied into spray gun, when reservoir is connected to it.

EFFECT: higher filter capacity.

6 cl, 7 dwg

Description

Field of Invention

The present invention relates to improvements related to or related to filters for fluid supply units. In particular, but not limited to, the present invention relates to fluid supply units in liquid spraying devices, for example spray guns, in particular hand spray guns with fluid supply units having a spray reservoir mounted on the spray gun.

BACKGROUND OF THE INVENTION

Sprayers are widely used in various industries for applying liquid to substrates. In known atomizers, the liquid is located in a reservoir attached to the atomizer, from which it enters the atomizer nozzle. When exiting the nozzle, the liquid is sprayed using compressed air supplied to the nozzle and forms an aerosol. The liquid can be supplied by gravity or sucked up, or, as has been practiced recently, pumped into the tank through the air intake pipe from the compressed air supply pipe to the tank or even from the compressed air pipe to the sprayer itself.

Sprayers are widely used in car repair shops to paint the body of a car repaired after an accident. A typical set of paintwork may include the application of a primer layer, a lower layer, an upper layer and a layer of transparent varnish. The presence of contaminants, such as particulate matter, in the sprayed liquid can ruin the surface of the paintwork, and large-scale remodeling work will be required to obtain an acceptable finish. In some cases, solid particles can clog the spray gun itself, which entails disassembling and cleaning. In addition, such a blockage can adversely affect the spraying parameters, which makes the resulting finish quality unacceptable, and to get an acceptable finish quality you will need to redo the work again. Alteration of the paintwork and, if necessary, disassembly and cleaning of the spray gun increase both material consumption and labor costs.

Existing methods for equipping said reservoir with a filter to remove contaminants from the liquid when it expires from the reservoir during use of the atomizer are already described. Typically, said reservoir has an outlet connected to the inlet of the atomizer, and said filter is placed across or inside said outlet. The specified exhaust channel usually has a small diameter compatible with the connection to the spray. The presence of solid particles in the liquid placed in the tank can lead to clogging of the filter, which leads to the restriction or sometimes to a complete stop of the liquid intake.

Such a restriction of fluid flow into the spray can adversely affect the spray parameters, which will make the resulting finish quality unacceptable, and you will need to redo the work to obtain an acceptable finish quality. Moreover, to dismantle a clogged filter and replace it with a new filter, it is necessary to equip the tank with a special hole. The filter replacement operation is time consuming and may require decantation of the remaining liquid in the tank, which, after replacing the filter, will need to be refilled into the tank. As a result, the risk of spillage and possible fluid contamination is increased. In addition, some liquids must be activated before spraying, and after activation they have a relatively short life time. Delays caused by clogging the filter can cause such liquids to become unusable, causing an additional cost increase.

Also described are methods of filtering a liquid to remove solid particles therefrom before or during the addition of liquid to said reservoir by using a filter mounted outside the reservoir. Such a filtering system eliminates the need to install a filter inside the tank, however, the filtering operation itself usually requires a certain amount of time due to the fact that the filter capacity is less than the speed at which liquid is poured into the tank. In addition, there is an increased risk of spillage if the rate of addition of fluid exceeds the filter capacity and the filter device overflows. In addition, dust or other airborne contaminants can enter the filtered liquid, which leads to the potential for the above problems.

Patent WO 98/32539 describes a reservoir for a nebulizer consisting of an outer vessel and an inner liner that fits snugly into the outer vessel. The specified liner is removable, which allows you to use a clean liner when changing the type of sprayed liquid, thereby reducing the amount of cleaning work. In one embodiment of the present invention (FIG. 12), said reservoir has an outlet at one end connected to the spray gun and at the other end a cap that is removed to add paint to the reservoir connected by the spray gun. In this embodiment of the present invention, all of the liquid sprayed by the atomizer passes through a strainer mounted inside the liner, said filter having a size and shape appropriate to the liner, which eliminates the need to filter the liquid when it is poured into the reservoir.

Patent WO 02/085533 describes a spray tank having an inlet closed by a removable cap, said cap being accessible when the tank is attached to the spray, which allows liquid to be added to the tank without disconnecting it from the spray. In one embodiment of the present invention, the possibility of using a removable “insert” filter attached to the inlet for filtering the liquid being poured into the reservoir is shown. In this embodiment of the present invention, said filter is not intended to reside inside said reservoir.

SUMMARY OF THE INVENTION

The subject of the present invention is such an improvement in the filter for fluid supply units used to supply fluid to the nebulizers, which provides the user with substantial benefits and advantages.

More specifically, at least one embodiment of the present invention is a filter for a fluid supply assembly that allows a simple method to add fluid to a reservoir, the impurities contained in said fluid being removed during fluid addition to the reservoir.

In addition, at least one of the embodiments of the present invention is a filter for the fluid supply unit having a large throughput, which allows you to quickly fill the tank with filtered spray liquid.

Further, at least one of the embodiments of the present invention is a filter for the fluid supply unit, which can remain in place when the reservoir with the filter in it is connected to the sprayer.

In addition, at least one of the embodiments of the present invention is a filter for the fluid supply unit, allowing the reservoir in which the filter is located to compress as fluid is consumed from the reservoir.

Other benefits and advantages of the present invention will be indicated below.

According to the first novelty element of the present invention, a filter is obtained for the fluid supply assembly described in claim 1.

Here, the term “liquid” is used to denote all types of fluid materials that can be applied to surfaces using a spray gun (regardless of whether these materials are intended for painting surfaces or not), including (but not limited to) paints, primers, polishes, varnishes and similar paint-like materials, as well as other liquid materials that can be applied in sprayed or non-sprayed form, depending on the properties and / or) the method of application of the material provided, and the concept of " liquid ”should be interpreted accordingly.

In accordance with the present invention, the cylindrical filter housing is placed inside the tank and can be positioned so that the surface area of the filter inside the tank is optimized in comparison with the filter volume. As a result, the filter has a high throughput, which allows you to quickly fill the tank while reducing the risk of spillage. Thus, the liquid can be filtered during pouring into the tank, which allows a filtered liquid to be supplied to the tank in the tank when the tank is connected to the gun. Due to this, the specified filter does not interfere with the flow of the filtered liquid supplied to the sprayer, and the risk of clogging of the sprayer or contamination of the treated surface with solid particles that may be contained in the sprayed liquid is significantly reduced or even completely eliminated.

It is preferable that the ratio of surface area to volume of said cylindrical body be such that the liquid can be filtered at a speed comparable with the rate of filling of the liquid, which will ensure quick filling of the tank without spilling liquid.

The indicated ratio of surface area to volume may vary depending on the characteristics of the liquid, for example, the viscosity and the size of the particles to be removed.

To the specified cylindrical body retained its shape, it can be relatively rigid. For example, the specified housing of the specified filter may be made of wire mesh. However, it is more preferred that said cylindrical body is flexible so that the filter can change its shape. For example, the filter housing may be made of a mesh made of a polymeric material such as polypropylene, polyester, polyamide (nylon) or any other suitable material. This will allow the filter to be delivered folded, which reduces the space required for storage and transportation. Further, if a reservoir is used, the design of which allows the reservoir to shrink as the fluid is consumed, the filter can remain in place inside the reservoir and match the compressed shape of the reservoir in shape. Depending on the material, application and requirements, for example with respect to pore size or uniformity, the mesh may be woven, non-woven or knitted. The specified mesh can be made in any suitable way, for example, a plastic mesh can be made by molding or extrusion.

The axial length of the specified filter can be selected so as to provide a suitable filtering rate for a particular liquid. For example, the axial length of the filter may, in essence, correspond to the depth of the tank into which the filter is mounted. Due to this, for a given diameter of the filler opening, maximization of the area of the working surface of the filter inside the tank is achieved. Moreover, if the tank is connected to a spray bottle with a filter inside the tank, as the liquid level in the tank drops, the liquid in the filter passes into the tank through a mesh casing. As a result, the flow of fluid into the atomizer does not decrease or is not interrupted when fluid passes through the specified mesh housing.

The support collar may have a size corresponding to the filling hole and is preferably equipped with an external protrusion at the external end for positioning and fixing the specified collar in the specified hole. The specified protrusion can be based on the far edge of the filler hole at the outer end of the wall bounding the filler hole. Alternatively, the filler opening may have a countersink socket on the outer end of the wall, into which said protrusion fits fully into the inner shoulder in the filler hole. This design does not allow the specified bead to completely pass through the filler hole.

The specified supporting collar may be made of a polymeric material, such as polypropylene, polyamide (nylon) or polyethylene, any other suitable material, and is preferably an integral part of the specified mesh housing of the specified filter. For example, said support flange may be cast at the outer end of the mesh body. Thus, the specified supporting flange fixes the specified mesh filter housing inside the specified tank, and its shape corresponds to the shape of the filler hole. For example, said support flange may be round, oval, square, or any other shape corresponding to the shape of the filler hole.

The specified filter may be equipped with devices that help maintain the cylindrical shape of the specified mesh housing, at least during the pouring of liquid into the specified tank. In one embodiment of the present invention, in order to maintain the cylindrical shape of the mesh housing, said filter may have supporting hoops covering the mesh housing and spaced apart along the axis between the ends of the mesh housing. Said carrier hoops may be integral parts of said mesh body, for example, said carrier hoops may be molded together with said mesh body. Preferably, said supporting hoops allow the filter to follow the shape of the reservoir if the design of said reservoir allows it to contract as the fluid is consumed. In another embodiment of the present invention, said support hoop may be coupled to a frame surrounding said mesh body within said reservoir. The specified frame can be formed by many legs extending from the specified flange at the open end of the specified mesh body to the basement element at the closed end of the specified mesh body. These legs are preferably spaced evenly and can be flexible, which allows the filter to follow the shape of the tank, for example, if the design of the specified tank allows it to compress as the fluid is consumed. In another case, said frame may be relatively rigid to maintain the shape of said filter both during the pouring of liquid into the tank and during the expenditure of fluid from the reservoir during use of the atomizer, for example, if the reservoir does not compress as the fluid is consumed. The specified frame may be an integral part of the specified mesh body, for example, the specified frame can be molded together with the specified mesh body.

According to a second novelty element of the present invention, a fluid supply assembly for use with liquid spraying apparatuses is described in claim 6.

Preferably, the filling hole is on the end wall of the tank. In one embodiment of the present invention, said reservoir consists of a top-open vessel and a lid for closing the open end of said vessel and forming said end wall in which there is a filling opening.

In most cases, this cap has an outlet connected to the spray gun. In one embodiment of the present invention, said outlet channel has an underwater hole made in said cover and separate from the filler hole, which leads into a cylindrical neck connected to the sprayer. This design allows you to leave the specified filter inside the specified tank when the specified tank is connected to the sprayer.

Said filling opening can be equipped with a removable plug, such as, for example, a screw cap, which can be removed when it is necessary to add liquid to the indicated tank, and is screwed again to close the filling opening when the tank is connected to the sprayer. This design provides access to the filler opening, allowing fluid to be added to the reservoir when said reservoir is connected to the sprayer.

Preferably, the size of said filler opening is larger than the size of said underwater opening, and both openings are offset from the central longitudinal axis of said reservoir. This design will improve access to the specified filling hole when the tank is connected to the spray, which allows you to add fluid to the tank without disconnecting the specified tank from the spray.

In another embodiment of the present invention, said filler opening is located in the center of said cap, and said outlet channel is a separate connector detachably attached to said cap, covering said filler hole, and having a cylindrical neck connected to the sprayer. This design allows you to disconnect the specified tank from the specified connector to gain access to the specified filling hole, when you want to add fluid to the specified tank. In this embodiment of the present invention, said filter is removed after adding fluid and before reconnecting said reservoir to said connector.

Said lid and vessel may be permanently bonded to each other along the edge of an opening in said vessel. For example, said lid and vessel may be glued or welded together to form a liquid tight connection. Alternatively, said lid and vessel may be detachably interconnected to provide a liquid tight connection. For example, the lid may be pressed against the vessel.

In one embodiment of the invention, said vessel is compressed as fluid from said reservoir is consumed. In this embodiment of the present invention, said vessel may have a flexible side wall and a relatively rigid base such that said vessel can stand upright on this base without any other support, and the side wall folds in such a way that as the fluid is consumed from the reservoir, said base moves toward said cap. The specified lid is relatively rigid and may have a hanging skirt that is placed inside and fixed around the inner edge of the open end of the specified vessel so that the specified vessel is supported by the specified cover. As a result, the stability of the reservoir filled with liquid and connected to the atomizer is improved, which facilitates the manipulation of the atomizer, especially if the reservoir contracts as the fluid is consumed. In order to provide additional support for said vessel, said cover may be equipped with an extension sleeve or frame covering said vessel.

In another embodiment of the present invention, said vessel is placed in an external container to which said tank is attached using a clip detachably attached to said external container on top of said lid. In this embodiment of the present invention, said reservoir is a liner in an external container, and after use, said reservoir can be discarded, a new reservoir placed in an external container and secured with a clip.

Preferably, said tank is adapted for detachable connection to a spray gun. For example, said reservoir and sprayer may be equipped with interacting bayonet fittings. This design allows you to conveniently connect the specified tank to and disconnect it from the specified spray. Alternatively, said reservoir and sprayer may be equipped with mating threaded connectors.

The inlet channel of the atomizer may have a socket into which a tube is inserted connecting the outlet channel of the tank to the specified inlet channel. The specified tank and spray can be equipped with interacting bayonet devices or mating threaded connectors designed for detachable connection of the tank with the spray. In one embodiment of the present invention, said tube and socket are equipped with bayonet structures interlocked within said socket. For example, the lugs on the tube enter the grooves in the nest. In another embodiment of the present invention, the sprayer and reservoir are equipped with bayonet structures that engage with each other outside of said socket. For example, the specified socket may have an external flange interacting with a pair of locking elements located on opposite sides of the specified tube. The specified socket may be an integral part of the sprayer or may be detachable. For example, the specified socket may be an adapter, one-piece or detachably attached to the specified spray.

The specified tank may be delivered empty with a filter installed in it, and the user himself fills the tank with liquid. Alternatively, the filter can be supplied separately, and the user inserts it into the filling hole before filling the tank with liquid. If the specified tank is compressible, it can be folded compactly for storage and transportation, and after use can be disposed of in the folded state. Said filter is preferably also compressible so that it can be delivered installed inside the compressible reservoir and disposed of with the reservoir after use.

Alternatively, said reservoir may be supplied pre-filled with liquid, and the neck closes hermetically until a reservoir is required to be connected to the atomizer. For example, said neck may have a removable plug or a tearable closure membrane. If a capping membrane is used, it may burst before or during the connection of the neck to the spray gun. This design allows you to supply a tank with a filter installed in it, which eliminates the need for the user to independently manufacture or install a filter when adding fluid to the specified tank.

Alternatively, the filter can be supplied separately, and the user installs it himself if it is necessary to add liquid to the tank.

Pre-filling can be used for liquids that can be packaged and stored until use without impairing their properties. Therefore, prefilling can be applied to liquids that can be supplied ready for use (i.e., not requiring modification to obtain a shade matching the existing shade). An example of such liquids is paints for the lower layer having a standard specific color or shade, and / or primers, or varnishes, which can be supplied as a concentrate and activated during use by exposure to an energy source, such as ultraviolet or visible light or electricity.

The specified device for supplying fluid can be used with a spray, forming a complete device for spraying. The specified spray can be used regardless of whether the supply is selected by gravity, pneumatic suction or compressed air.

Brief Description of the Drawings

Below, purely by way of example, with reference to the attached drawings, a more detailed description of embodiments of the present invention is given.

Figure 1 shows a perspective view of a spray for use with a fluid supply unit, an embodiment of the present invention.

Figure 2 presents the end view of the adapter for the sprayer shown in figure 1.

FIG. 3 is a perspective view of a fluid supply assembly for use with the atomizer of FIGS. 1 and 2 having a filter according to a first embodiment of the present invention.

Figure 4 presents a perspective view of the filter shown in figure 3.

Figure 5 presents a perspective exploded view of the tank shown in figure 3.

FIG. 6 is a perspective view of a fluid supply assembly for use with the atomizer of FIGS. 1 and 2 having a filter according to a second embodiment of the present invention; and

FIG. 7 is a perspective view of the filter of FIG. 6.

Detailed Description of Embodiments of the Present Invention

First, we turn to FIGS. 1-5, which show a manual spray gun with a fluid supply by gravity 1 (Fig. 1), having an inlet adapter 2 (Figs. 1 and 2) for detachable connection of the fluid supply unit 3 (Figs. 3-5) .

The atomizer 1 (Fig. 1) has a housing 4, a handle 5, which protrudes downward from the rear end of the housing, and a spray nozzle 6 at the front end of the housing. The atomizer 1 is manually actuated by pressing the trigger 7, which is mounted on an axis on the sides of the atomizer 1.

The inlet adapter 2 (FIGS. 1 and 2) is located on top of the housing 4 and communicates with the internal channel (not visible) passing through the housing 4 to the nozzle 6.

In this embodiment, the inlet adapter 2 is removable, for example screwed to the housing 4. This design allows the nozzle 1 to be adapted for use with various types of fluid supply units by selecting and installing an appropriate adapter 2. In addition, this design allows you to replace the damaged adapter 2.

In other embodiments of the present invention (not visible), the inlet adapter 2 may be an integral part of the spray gun housing 4. For example, the inlet adapter 2 may be manufactured as an integral part of the spray gun housing 4 or may be manufactured separately and permanently attached to the spray gun housing 4. alternatively, the adapter 2 may be lowered, and the fluid supply unit is mounted directly on the housing 4 of the atomizer 1.

In use, the spray gun 1 is connected via a connector 8 located at the lower end of the handle 5 to a source of compressed air (not visible), and when the user pulls the trigger, compressed air enters the nozzle 6 through the spray gun. As a result, a liquid, such as paint, flows by gravity from the supply unit liquid 3 into the nozzle 6, is sprayed at the outlet of the nozzle 6 with compressed air and forms an aerosol emerging from the nozzle 6.

Now refer to FIGS. 3-5, where a fluid supply unit 3 is shown, consisting of a reservoir 9 for spraying fluid (not visible) and a filter 10 for removing particulate matter while adding said fluid to the reservoir.

The tank 9 consists of a vessel 11 and a cover 12 (figure 5). The vessel 11 is usually in the form of a cylinder having an open end 11A and a closed end 11B, interconnected by a flexible side wall 11C. In this embodiment, the vessel 11 is transparent and is made from a single preform of a polymeric material, preferably polyethylene or polypropylene, by thermoforming. The container 11 may be of any suitable size, however, if the container is intended for use with a manual spray gun, then to facilitate handling of the spray gun to which the reservoir 9 is connected, the container typically has a capacity of 250, 500 or 800 ml. The side wall 11C may have labels (not visible) to indicate the volume of liquid in the tank 9.

Said cover 12 is usually ring-shaped and in this embodiment of the present invention is also made of a transparent polymeric material, preferably polyethylene or polypropylene, by injection molding or using other suitable technology. The cover 12 has a skirt 12A hanging from the outer edge 12B. The specified skirt 12A is inserted into the open end 11A of the vessel 11 and rests on the annular step 11D in the side wall 11C. The outer edge 12B of said cover 12 rests on the outer flange 11E at the open end of the vessel 11. The cover 12 is permanently attached to the specified vessel by gluing or welding the skirt 12A to the side wall 11C and the outer edge 12B to the flange 11E.

The specified cover 12 is relatively rigid in comparison with the side wall 11C of the specified vessel and ensures that the open end 11A of the vessel 11 is ring-shaped. The closed end 11B of the vessel 11 is also relatively rigid in comparison with the side wall 11C and forms a flat base on which the specified tank 9 can stand upright without any other support, so that the side wall 11C protrudes upward (figure 3) .

The side wall 11C is flexible and can fold as the liquid flows from the reservoir 9 into the atomizer 1. When the side wall 11C is compressed, the relatively rigid base 11B retains its shape, but moves toward the cover 12. The side wall 11C is compressed like plastic without tearing (for example, as a result of splitting, tearing or cracking).

The convex upper surface 12C of said cover 12 has an inlet or filler opening 12D and an outlet or underwater opening 12E. The specified filling hole 12D, the diameter of which is approximately half the diameter of the lid 12, on the upper surface 12C is limited to an annular sleeve 14 having an external screw thread 14A. Said filling opening 12D is closed by a removable screw cap 15 having a skirt 15A with an internal screw thread corresponding to the external screw thread 14A of the sleeve 14.

The specified feed hole 12E, the diameter of which is approximately one sixth of the diameter of the cover 12, is limited on the upper surface 12C by a cylindrical neck 16. The size of the neck 16 is selected so that it fits tightly into the countersink hole 17 (Fig. 2) at the outer free end of the specified adapter 2.

In this implementation of the present invention, the neck 16 has external annular ribs 16A providing a liquid-tight joint of the surface of the specified neck with the surface of the specified countersink hole 17. Of course, you can use any other suitable sealing methods, for example, the equipment countersink holes 17 and / or neck 16 one or several ring gaskets.

The diameter of the filler hole 12D is much larger than the diameter of the filler hole 12E, and this diameter is selected as large as possible to facilitate the addition of fluid to the reservoir 9 from the same end as the filler hole 12E. This allows you to add fluid to the tank through the filler hole 12D when the tank is in an upright position and is either free standing on the indicated base, or the specified outlet 12E is connected to the spray gun 1.

In this implementation of the present invention, the ratio of the cross-sectional area of the filler opening 12D to the cross-sectional area of the supply opening 12E is approximately 9: 1, however, it is understood that other diameters of the openings 12D, 12E can be used. The holes 12D, 12E in the lid 12 are offset from the central longitudinal axis of the tank 9, and the parts extending them upward are located at an angle to the specified longitudinal axis. This design improves access to the filler opening 12D by allowing fluid to be added to the reservoir 9 when said reservoir 9 is connected to the atomizer 1.

In this implementation of the present invention, the upper part of the hole 12D is located at an angle of about 17 °, and the upper part of the hole 12E is at an angle of about 13 ° to the specified longitudinal axis of the tank 9, i.e. the angle between these parts is approximately 30 °. Obviously, the upper parts of one or both of the holes 12D, 12E can be parallel to the specified longitudinal axis or at any desired angle to the specified longitudinal axis.

The cover 12 is also equipped with two engaging elements 18, 18 'located on opposite sides and spaced from the neck 16. These engaging elements 18, 18', the neck 16 and the sleeve 14 are located on the same diameter of the cover 12.

The engaging elements 18, 18 'are identical to each other and have enlarged heads 18A, 18A', respectively, with beveled faces 18B, 18B 'ending in cut-through locking ribs 18C, 18C'.

The inlet adapter 2 on the nozzle has an outer flange 2A at the outer end, which cooperates with the engaging elements 18, 18 'for releasably attaching said reservoir to the nozzle when the neck 16 enters the countersink hole 17.

As best seen in FIG. 2, the flange 2A has four arcuate recesses 19, 20, 21, 22 equally spaced around the circumference on the outside so that the recesses 19 and 21 are opposite to each other, and the recesses 20 and 22 are opposite to each other.

Each of the recesses 19, 20, 21, 22 leads in a clockwise direction (as shown in figure 2) through the protrusions of the cams 19A, 20A, 21A, 22A to the flat sections 23, 24, 25, 26, which end in the stops 23A 24A, 25A, 26A.

When used to attach the reservoir 9 to the inlet adapter 2, the engaging elements 18, 18 ′ are aligned with a pair of opposing recesses 19, 21 or 20, 22 in the flange 2A. Then the neck 16 is inserted into the countersink hole 17 so that the enlarged heads 18A, 18A 'at the far ends of the engaging elements 18, 18' pass through the combined recesses 19, 21 or 20, 22.

Then the reservoir 9 rotates relative to the inlet adapter 2, while the engaging elements 18, 18 'extend over the protrusions of the cams 19A, 21A or 20A, 22A and meet with the locking ribs 18C, 18C' of the heads 18A, 18A 'behind the flat sections 23, 25 or 24 , 26. Thus, said reservoir 9 is attached to said inlet adapter 2, and axial separation of the reservoir 9 from the inlet adapter 2 is prevented. By performing the reverse steps, you can remove the tank 9 from the inlet adapter 2.

The offset location of the neck 16 from the central longitudinal axis of the tank 9 in combination with pressure and rotation to secure the tank 9 can cause the tank to shift the center of gravity of the body 4 of the spray gun 1 in the lateral direction. The presence of two pairs of opposite recesses 19, 21 and 20, 22 allows you to attach the tank 9 using these two pairs of recesses, which reduces or eliminates the skew of the tank 9. This improves the balancing of the Assembly of the spray 1 - tank 9, which facilitates the manipulation of the spray.

To remove solid particles from the liquid added to the tank 9 through the filling hole 12D with the cap 15 removed, a filter 10 is inserted into the filling hole 12D, reaching the bottom of the tank 9.

As best seen in FIG. 4, said filter 10 has a mesh housing 10A closed at one end and open at the other end. In this implementation of the present invention, the mesh body 10A is made of a polymeric material, such as polypropylene, polyester or polyamide (nylon), and has a pore size necessary to remove particles of 40 microns or more, potentially up to 1000 microns. It will be appreciated that said mesh housing 10A may be made of other materials and have any desired pore size appropriate for the particular application.

The specified filter 10 has a relatively rigid annular bead 27 at the open end of the mesh housing 10A. The specified shoulder 27 is made of a polymeric material, such as polyamide (nylon), polypropylene or polyethylene, and is an integral part of the specified mesh housing 10A, for example, the shoulder 27 may be cast on the mesh housing 10A.

The size of the specified flange 27 is selected so that it fits tightly into the sleeve 14, and the specified flange has an outer annular protrusion 27A at the outer end, which, when the filter 10 is placed inside the tank 9, rests on the outer end of the sleeve 14 and provides a tight seal between the screw cap 15 and the filling hole 12D. The mesh housing 10A of the filter 10 is usually in the form of a cylinder with a maximum diameter corresponding to the diameter of the filling hole 12D, so that the specified filter is easily inserted into the filling hole 12.

In this implementation of the present invention, the axial length of the mesh housing 10A is selected such that when the shoulder 27 is inserted into the sleeve 14, the closed end of the mesh housing is located near the bottom of the reservoir 9. This allows you to optimize the ratio of surface area to volume of the cylindrical mesh housing 10A in accordance with the pore size of the specified filter and added fluid properties.

As a result, the filter 10 has a high throughput, which allows you to pour liquid, and the tank 9 through the filling hole 12D without overflowing the filter or spillage of liquid. Thus, the reservoir 9 is quickly filled with liquid filtered to remove particulate matter.

The specified mesh housing 10A is flexible, which allows it to be compressed together with the reservoir 9 as the fluid is consumed during operation of the atomizer. Due to this, after filling, the filter 10 can be left in its place inside the tank 9, and a screw cap 15 can be screwed on to close the filler opening 12D and fasten the filter 10 in its place.

The outlet 12E is separated from the filling opening 12D, and the presence of the filter 10 inside the tank 9 does not interfere with the flow of fluid through the neck 16 to the sprayer 1. In addition, the tank 9 contains already filtered liquid entering the sprayer 1, therefore, the fluid flow is independent of the filtering speed liquid in the process of its expenditure from the reservoir 9.

As the liquid level drops in the tank 9, the liquid in the mesh housing 10A can pass through the mesh housing 10A into the tank 9. As a result, filtering the volume of liquid remaining in the filter housing 10A when filling the tank 9 does not adversely affect the flow of liquid into the atomizer 1 .

In an alternative embodiment of the present invention, said filter 10 can be removed after filling the reservoir with liquid, and before connecting the reservoir 9 containing the filtered liquid to the atomizer 1, the filling opening 12D is closed by screwing on the screw cap 15.

If the filter 10 remains in the tank 9, then the risk of liquid spillage when removing the specified filter is eliminated. In addition, if you want to replenish the reservoir 9 with liquid, you can unscrew the screw cap 15 and pour liquid into the reservoir through the filling hole 12D, inside which there is already a filter designed to remove solid particles.

We now turn to FIGS. 6 and 7, which show a fluid supply assembly having an alternative filter in accordance with the subject of the present invention. For convenience, the same numbers only increased by 100 will be used to designate parts corresponding to parts in a previous implementation of the present invention.

As shown in FIG. 7, the mesh housing 110A of the filter 110 is housed inside the support frame 128, which is an integral part of the collar 127. In this embodiment, the support frame 128 has four legs 128A extending axially from the collar 127 and connected to the bottom ring 128B at the closed end of the filter housing 110A. The specified support frame 128 helps to maintain the cylindrical shape of the filter housing 110A when adding fluid to the reservoir 109.

And in this embodiment of the present invention, the surface area of the mesh housing 110A is optimized in comparison with the volume of the filter 110 in order to achieve a high throughput that ensures that the reservoir 109 is quickly filled with filtered fluid.

In this embodiment of the present invention, the legs 128A are relatively rigid, which enhances and maintains the cylindrical shape of the mesh body 110A. In this embodiment of the present invention, the filter 110 is removed after filling the reservoir 109, and before attaching the reservoir 109 to the spray gun 1, the filler opening 112D is closed by a screw cap 115. Due to this design, the filter 110 does not prevent the reservoir 109 from contracting as fluid is consumed. In other respects, the construction and functioning of the details of this implementation of the present invention are similar to those in previous implementations of the present invention and are clear from the above.

In a modification (not shown), the frame 128 may be replaced by a plurality of supporting hoops (not shown) spanning said mesh body 110A and spaced apart along an axis. These carrier hoops provide structural reinforcement necessary to maintain the cylindrical shape of the mesh housing 110A when adding fluid to the reservoir 109, while simultaneously allowing the filter 110 to contract with the reservoir 109 as the fluid is consumed. This design allows, after filling with liquid, to connect the reservoir 109 to the atomizer, leaving the specified filter 110 in its place inside the reservoir 109. In an alternative embodiment, the frame 128 may have a structure that allows the filter 110 to fold, for example, these legs 128 may be flexible.

From the foregoing description of exemplary embodiments of the present invention, it is understood that if there is a filler opening 12D, 112D separate from the supply opening 12E, 112E, the liquid can be poured into the reservoir 9, 109 having said reservoir 9, 109 connected to the atomizer 1. For this, atomizer 1 flips from its normal operating position so that the tank 9, 109 is in line with the top of the lid 12, 112 so that all the glass liquid remaining in the tank 9, 109 is at the bottom (it may be necessary to unfold the tank 9, 109 from his squeezed position, to which he moved as a result of the expenditure of paint in the process of work). Then, the screw cap 15, 115 is removed and liquid can be added without risk of spillage. Then the cap 15, 115 is screwed on again and the spray gun 1 is turned to its normal operating position to continue spraying.

Alternatively, the reservoir 9, 109 can be disconnected from the spray gun 1 and put upside down with the lid 12, 112 upright, then remove the screw cap 15, 115 and add fluid (the reservoir 9,109 may need to be deployed from its compressed position, to which it moved paint consumption during operation). Then the cap 15, 115 is screwed on again and the reservoir 9, 109 is connected to the spray gun 1 to continue spraying.

After spraying is completed, the tank 9, 109 can be disconnected from the spray gun 1 and temporarily store the paint remaining in the tank 9, 109 by covering the supply opening 12E, 112E with any suitable plug. Then the reservoir 9, 109 can be reconnected to the atomizer 1 and use the remaining liquid. Alternatively, the reservoir 9, 109 can be disposed of together with the filter 10, 110, having previously closed the supply opening 12E, 112E.

It is understood that the present invention is not limited to the embodiments described above.

For example, a design in which the filling opening is separated from the supply opening allows you to leave the filter in its place when connecting the specified tank to the sprayer and add fluid to the tank connected to the sprayer. Said filling opening and supply opening can be equipped with a lid at the same end of the tank. Alternatively, the filling opening may be equipped in the side wall or the bottom wall of the vessel, and the supply opening in the lid.

In another embodiment of the present invention, said cap may have a centrally located filling opening into which the filter is mounted, and a separate connector having an outlet neck for securing the reservoir to the sprayer. After adding fluid to the tank, this connector is detachably attached to the cap along the perimeter of the filler opening and adapts the cap for connection to the sprayer. In this embodiment of the present invention, said reservoir may be removed from said connector, and liquid is added to the reservoir through a filter inserted in the filler opening. The specified filter is then removed, and the tank is connected to the specified connector for mounting the tank on the spray.

Said lid and vessel may be permanently bonded to each other as described above. Alternatively, said lid and vessel may be detachably interconnected. For example, said vessel may be an insert for a rigid external container, said lid being detachably attached to said insert using a cage screwed onto the external container. This type of fluid supply device forms the subject of our International Patent Application, published July 30, 1998 under the number WO 98/32539.

The specified reservoir may shrink as fluid is consumed. In this embodiment of the present invention, said filter may be flexible, which allows the filter to compress with the reservoir if said filter is left in place when said reservoir is connected to the atomizer. Alternatively, the filter may be stiff compared to the specified tank, and then the filter must be removed before connecting the tank to the spray gun.

The specified tank may be supplied empty with a filter installed in it, and the user only needs to remove the screw cap and fill the tank with spray liquid. Alternatively, the filter can be supplied separately, and the user inserts it into the filling hole before filling the tank with liquid.

If the reservoir is compressible, it can be delivered folded, which reduces the space required during storage and transportation, and the end user deploys the reservoir before adding fluid. This design allows you to deliver the tank when folded with the filter installed in it or separately, and in the latter case, the end user inserts the filter into the filling hole.

In another embodiment of the present invention, the reservoir may be supplied pre-filled with liquid. In this embodiment of the present invention, the filter can be supplied separately, and the user installs it himself if it is necessary to add liquid to the tank. Alternatively, the tank may be supplied with a filter installed therein, and the end user simply adds fluid when required.

In another embodiment of the present invention, said reservoir may be rigid. In this embodiment of the present invention, said filter may be flexible or rigid, and may remain in place when said reservoir is connected to the atomizer. The specified tank can be supplied empty or pre-filled with liquid, both with the filter installed in it, and separately. In this design, in order for the liquid to flow out of the reservoir during operation, an air valve is required in the fluid supply system, for example, said reservoir may have an air inlet opening that can be opened when the reservoir is connected to the atomizer.

For specialists competent in this field, other modifications and improvements are obvious.

It is now obvious that the implementation of the present invention allows to obtain a high-throughput suspension filter for use in the fluid supply unit for spraying devices, such as spray guns, providing quick filling of the tank. This allows you to filter the fluid added to the tank, providing a filtered fluid to the sprayer.

Further, if the filling opening is separate from the supply opening, the filter can remain in place when the tank is connected to the sprayer, and the filter can be used immediately when it is necessary to replenish the tank with liquid.

In addition, if the specified filter has a flexible mesh housing, such a filter can be used with tanks that are compressed as fluid is consumed, and with rigid tanks.

It is also understood that the embodiments of the present invention described herein are intended to illustrate various aspects and applications of the present invention, and that the features of these embodiments can be used separately from or in combination with any other features of the same or any other embodiment of the present invention.

Further, although the described and illustrated embodiments of the present invention are the best methods currently known to the applicant, it is understood that the present invention is not limited to them and that, without going beyond the patent claims listed here, various changes and improvements can be made.

Claims (6)

1. Filter (10, 110) for the fluid supply unit, which includes a reservoir (9, 109), connected to a spray device such as a spray gun (1), a filter (10, 110), which is an elongated tubular body (10A 110A), open at one end and closed at the other end, while at the open end there is a support flange (27, 127), which is inserted into the filling hole (12D) of the tank (9, 109) and fixes the specified open end in such a way that the filter housing (10A, 110A) moves away from the hole (12D) in the tank (9, 109) when adding liquid to the reservoir (9, 109) through the filling hole (12D), while the tubular body (10A, 110A) of the filter (10, 110) is characterized by the fact that it has sufficient rigidity to maintain its elongated tubular shape and its surface area and volume after it placement in the tank (9, 109) allows you to add fluid to the tank (9, 109) during operation to create a reservoir of filtered fluid in the tank (9, 109) that can be fed into the spray gun (1) when the tank (9 , 109) will be connected to the spray gun (1). 2. The filter according to claim 1, characterized in that the tubular filter housing (10, 110) has such a cross section that the filter (10, 110) can be lowered into the tank (9, 109) to install a support collar (27, 127 ) in the filler hole (12D). 3. The filter according to claim 2, characterized in that the tubular filter housing (10, 110) has such an axial length that is essentially equal to the depth of the reservoir (9, 109) into which this filter is lowered. 4. The filter according to claim 1, characterized in that the supporting flange (27, 127) has an outer edge (27A, 127A) at the outer end located around the large edge of the filler hole (12D), the purpose of which is to install and fix the flange (27, 127) in the hole (12D). 5. The filter according to claim 1, characterized in that the supporting flange (127) is connected to the frame (128) located around the circumference of the tubular housing (110A) of the filter (10) in the tank (9, 109), wherein the frame consists of many legs (128A) protruding from the support flange (127) at the open end of the tubular body (110A) and ending on the lower ring (128B) on the closed end of the tubular body. 6. The fluid supply unit used in spraying devices, such as a spray gun, while this fluid supply unit consists of a reservoir (9, 109) for containing liquid, and the reservoir (9, 109) can be connected to the gun during operation sprayer (1) for supplying fluid to the inlet of the spray gun (1) and has a filler hole (12D) for adding fluid and a filter (10, 110) for filtering fluid topped up in the tank (9, 109) through the filler opening (12D) the filter (10, 110) consists of an elongated tubular body CA (10A, 110A), closed at one end and open at the other end, and at the open end there is a support flange (27, 127), which is inserted into the filling hole (12D) so that the filter housing (10A, 110A) leaves from the hole (12D) in the tank (9, 109) while adding liquid to the tank (9, 109) through the filler hole (12D), while the tubular body (10A, 110A) of the filter (10, 110) is characterized in that it possesses sufficient rigidity to maintain its elongated tubular shape and its surface area and volume after it is placed in the reserve Voire (9, 109) allows you to add fluid to the reservoir (9, 109), which is filtered when added to the reservoir (9, 109) to create a reservoir of filtered fluid in the reservoir (9, 109) that can be fed into the spray gun ( 1) when the reservoir (9, 109) is connected to the spray gun (1).

Images