05/219699

12/25/1973

01/21/1972

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239/526

251/111, 251/98, 239/583

B05B9/01; B05B9/00; B05B1/30

251/111,98 239/526-528,412,583,414

3380705	Spray gun	April 1968	Enssle
3515355	AIRLESS SPRAY GUN	June 1970	Wagner
3190564	Spray coating apparatus for spraying liquid coating material under high pressure	June 1965	Liedberg
3410491	Valve means	November 1968	Malec

Wood Jr., Henson M.

Love, John J.

I claim

1. An airless spray gun comprising,

2. An airless spray gun comprising,

3. The airless spray gun of claim 2 wherein the intersection of said cut-away portion and said channel is "flat" to permit the said rotation of said first member.

4. An airless spray gun comprising,

5. The airless spray gun of claim 4 wherein said second member has a rearward end and wherein a tension cap means threadably extends into the rearward end of said second member for engagement with one end of said tensioning spring to permit the selective tensioning of said spring.

6. An airless spray gun comprising,

Conventional airless spray guns have an extremely large number of component parts which greatly adds to the cost of manufacturing the same. Conventional airless spray guns are not easily assembled and disassembled due to the means for mounting the valve rods in the gun. The assembly and disassembly of the conventional airless spray guns is also difficult and time consuming due to the construction of the trigger locking assemblies. The present means for manufacturing the valve seats of the conventional airless spray guns is also time consuming and expensive.

Therefore, it is a principal object of this invention to provide an improved airless spray gun.

A further object of this invention is to provide an airless spray gun having a substantially reduced number of component parts.

A further object of this invention is to provide an airless spray gun which is easily manufactured.

A further object of this invention is to provide an airless spray gun including novel means for mounting the valve rod therein.

A further object of this invention is to provide an airless spray gun which is quickly and easily assembled and disassembled.

A further object of this invention is to provide an airless spray gun having a novel valve seat provided therein.

A further object of this invention is to provide an airless spray gun which is efficient in operation, durable in use and refined in appearance.

These and other objects will be apparent to those skilled in the art.

This invention consists in the construction, arrangements, and combination of the various parts of the device, whereby the objects contemplated are attained as hereinafter more fully set forth, specifically pointed out in the claims, and illustrated in the accompanying drawings, in which:

FIG. 1 is a side view of the gun of this invention.

FIG. 2 is a top view of the gun as seen along lines 2--2 of FIG. 1.

FIG. 3 is a partial sectional view of the gun.

FIG. 4 is an enlarged sectional view as seen along lines 4--4 of FIG. 3.

FIG. 5 is a sectional view similar to FIG. 3 except that the trigger is shown in its depressed position.

FIG. 6 is an exploded perspective view of the nozzle assembly, manifold assembly and trigger locking assembly.

FIG. 7 is an enlarged sectional view as seen along lines 7--7 of FIG. 6; and

FIG. 8 is a side view of the trigger sleeve as it would appear after being rotated to permit its removal from the gun.

The airless spray gun of this invention is referred to generally by the reference numeral 10 and includes a handle 12 which extends downwardly from gun body 14. For purposes of description, the numeral 16 designates a wall member which extends downwardly from the forward end of body 14 and thence defines a trigger guard 18. Bore 20 extends through body 14 and is aligned with a bore 22 extending through wall member 16. The bores 20 and 22 may be drilled in the gun in one operation due to their aligned relationship and due to the fact that they have the same diameters which substantially reduces the cost of manufacturing the gun.

Manifold 24 has a cylindrical portion 26 which is received by the bore 22 as seen in FIG. 3 and which is maintained therein by means of manifold retainer nut 28 threadably secured to the rearward end thereof. Manifold 24 is prevented from rotational movement with respect to the gun body by means of manifold pin 30 extending rearwardly from the manifold 24 into the bore 32 formed in wall member 16. Manifold connector 34 extends downwardly from manifold 24 for connection to a source of spray material.

The numeral 36 refers to a carbide valve seat positioned in valve tip 38 and maintained therein by valve sleeve 40 which is threadably received by valve tip 38 as illustrated in FIG. 3. Valve tip 38 is threadably received by the forward end of manifold 24 so that valve sleeve 40 is positioned in bore 42 of manifold 24. A nylon valve seal 44 is positioned forwardly of tip 38 with spray nozzle 46 being positioned forwardly of seal 44. Valve gasket 45 is positioned between the forward end of manifold 24 and the head of the valve tip 38. Nozzle 46 and seal 44 are maintained in position by the spray nozzle retainer 48 which is threadably mounted on manifold 42 as seen in FIG. 3.

Valve rod 50 is longitudinally movably received by valve sleeve 40 and has a valve ball 52 mounted on the forward end thereof adapted to seat upon the valve seat 36. Valve rod 50 has a transversely extending valve pin 54 at its forward end which is detachably received by connecting rod connector 56. Connector 56 is provided with a circular bore 58 extending inwardly thereinto from its forward end. A pair of oppositely disposed grooves 60 and 62 are formed in connector 56 which communicate with bore 58 as seen in the drawings. The grooves 60 and 62 are adapted to removably receive the opposite ends of the valve pin 54 so that longitudinal movement of connector 56 will cause longitudinal movement of rod 50.

Connector rod 64 is threadably secured to the rearward end of connector 56 and extends rearwardly therefrom through a Teflon packing 65 and through a manifold packing nut 66 threadably mounted in manifold 24. Lock nut 68 prevents rod 64 from becoming accidentally disconnected from connector 56.

Trigger sleeve 70 is slidably mounted in bore 20 and has a bore 72 extending therethrough which receives the connecting rod 64. The rearward end of bore 72 is provided with an enlarged diameter portion to receive the snap-ring 74 which is detachably secured to the rod 64. Thus, rearward movement of sleeve 70 causes rod 64 and the components secured thereto to be moved rearwardly. Sleeve 70 has a vertical groove 76 at its forward end which is adapted to receive the upper end of trigger 78. Trigger 78 is pivoted at its upper end by means of trigger screw 80.

Sleeve 70 is provided with a milled "flat" 82 which extends forwardly from the rearward end thereof. Sleeve 70 is also provided with a channel 84 which is formed therein forwardly of the rearward end thereof and which extends transversely with respect to the longitudinal axis of the sleeve and which communicates with the forward end of the "flat" 82. A "flat" 86 is formed at the intersection of "flat" 82 and channel 84. Locating pin 85 extends through the body 14 and through the channel 84 of sleeve 70 to limit the rearward and forward movement of the sleeve and to maintain the sleeve 70 within the bore 20.

The forward end of trigger spring 88 is received in the rearward end of the enlarged diameter portion of the bore 72. The rearward end of spring 88 is received by bore 90 in sleeve lock 92. Sleeve lock 92 has a channel 98 formed therein which is transversely disposed with respect to the longitudinal axis thereof which is adapted to receive the locator pin 100 extending through body 14. Channel 98 has a sufficient vertical height to permit the sleeve lock 92 to be selectively sufficiently rotated to permit the locking of the trigger as will be explained hereinafter.

Tension cap 102 is adjustably threadably mounted in sleeve lock 92 as seen in FIG. 3 to permit the selective tension adjustment of spring 88 since the forward end of cap 102 engages the rearward end of the spring 88. Lock pin 104 extends forwardly from the forward end of sleeve lock 92 and terminates rearwardly of the rearward end of trigger sleeve 70 when the trigger is in its normal position (FIG. 3).

The normal method of operation is as follows. Assuming that the gun is in its assembled condition and that the trigger is in its normal position as illustrated in FIG. 3, the spray fluid will not bypass the valve ball 52 since the spring 88 urges the valve ball 52 into seating engagement with the valve seat 36. It can be seen that the rearward ends of the grooves 60 and 62 bear against the rearward ends of the valve pin 54 to urge the valve rod 50 towards the valve seat 36. With the lock knob 94 in its unlocked position as seen in FIGS. 3 and 5, pivotal movement of the trigger 78 causes the trigger sleeve 70 to be slidably moved rearwardly in the bore 20. Rearward slidable movement of the trigger sleeve 70 causes the connecting rod 64 to pull the valve rod 50 rearwardly from the valve seat 36. Rearward slidable movement of the trigger sleeve 70 is permitted since the lock pin 104 will be received by the "flat" 82. The trigger may be locked by simply rotated the lock knob 94 which causes the sleeve lock 92 to be rotated. Rotation of the sleeve lock 92 to its locked position causes the lock pin 104 to be moved with respect to the "flat" 82 so that the lock pin 104 will be closely adjacent the rearward end of the trigger sleeve 70. When the lock knob is in its locked position, the pin 104 prevents the trigger sleeve 70 from slidably moving rearwardly since the pin 104 will no longer be received by the "flat" 82 but will engage the rearward end of the trigger sleeve 70.

The construction of the gun permits the valve rod 50 to be removed therefrom without disassembling the entire gun as is the case with most conventional guns. The valve rod 50 is removed by simply removing the spray nozzle retainer 48 and the valve seal 44 from the forward end of the manifold. The valve tip 38 is then threadably removed from the manifold 24 which exposes the forward end of the valve rod 50. The valve rod 50 is then grasped and pivoted or moved with respect to the connecting rod connector 56 so that one of the pins of the valve pin 54 can be disengaged from its respective groove which then permits the valve rod 50 to be removed from the connecting rod connector 56. The relationship of the diameters of the valve rod 50, opening 58 and the width of the grooves 60 and 62 is such that the valve rod 50 may be sufficiently pivoted or moved to cause the disengagement of the valve pin elements from the grooves 60 and 62. Thus, the value rod 50 can be removed from the manifold without removing the connecting rod connector 56 or any of the components rearwardly thereof.

If it is desired to further disassemble the gun, the manifold packing nut 66 and the manifold retainer nut 28 are also removed from the rearward end of the manifold 24. The trigger screw 80 is then removed to permit the trigger to be moved downwardly so that the trigger may be disengaged from the vertical groove 76 of trigger sleeve 70. The trigger sleeve 70 is then manually rotated with respect to the locating pin 85 so that the trigger sleeve 70 may be removed from the bore 20 in a forwardly direction therefrom. This is made possible by the "flat" 86 which permits the rotation of the sleeve 70 so that the "flat" 82 will be positioned over the locating pin 85. When the "flat" 82 is so located, the sleeve 70 may be slidably moved forwardly from the bore 20 without removing the locator pin 85. The snap ring 74 may then be removed from the connecting rod 64 which permits substantially complete disassembly of the gun. The lock mechanism may be removed from the gun by removing the locator pin 100.

FIG. 7 illustrates the configuration of the valve seat 36 in somewhat greater detail. The seat 36 is formed by casting the same from carbide. The opening 110 would be formed during the casting and would have the angularly disposed surfaces 112 and 113. The opening 110 is then ground and lapped at the intersection of the surfaces 112 and 113 so that a surface 114 is formed which is tangent to valve ball 52. It is easier to grind a tangent on the carbide where the two surfaces 112 and 113 intersect then to grind an entire single angle cone. The intersection of the surfaces 112 and 113 requires very little grinding and lapping as compared to a normal seat of a single angle which must be ground over its entire internal surface and substantially reduces grinding and overlapping time.