1. Field
This disclosure relates generally to the field of washing devices for use in packing houses, and more particularly to a unique sprayer swivel body for a packing house carcass washer.
2. Description of Related Art
Meat packing houses or slaughter houses utilize a variety of machinery to clean animal carcasses. Washing machines that spray pressurized jets of water onto animal carcasses are generally known within the industry. Particular to packing houses for large animals, such as beef or pork facilities, washing devices have long been used which include a number of spaced apart spray bars, each bar having a plurality of openings through which pressurized water is sprayed directly onto an animal carcass to remove debris, blood and the like.
These systems may include two (2) or more spray assemblies spaced apart to form an alleyway. Carcasses, often hanging from shackles, are transported along the alleyway between the rows of spray bars so that all sides of the carcass are washed.
It is also common for the spray bars to be mounted on racks to form a sprayer wall assembly. Multiple spray bars are spaced apart and aligned such that the spray nozzles on each spray bar are generally oriented in the same direction, aimed generally inward the alley way. It should be understood that the orientation of the spray bars and spray wall assemblies can vary. Regardless of the spray wall orientation or composition, animal carcasses are transported between the spaced apart sprayer walls such that all sides of the carcass are sprayed.
Known spray devices include a water source that is connected to a water valve, sometimes called a swivel body in the industry. The water valve or swivel body directs the water source through an impeller shaft into a water spray line. Pressurized water is then forced through spray nozzles or jets formed into each water line for application directly onto the animal carcass. In known devices, the connection between the water valve and the water spray line is rigid. A number of replaceable bushings are utilized within the water valve to limit or control water leakage between the valve and the impeller shaft and between the valve and the water spray line. At least one set screw is secured through the water valve body to maintain each bushing in place.
Currently, as large animal carcasses travel along the line and move between the water washing walls, they are subjected to the forcible water spray that causes the carcasses to pivot, swivel and swing side to side. It is common for the animal carcasses to forcibly contact the water spray lines, the water valves and other parts of the assembly.
Because the impeller shaft is rigidly fixed within the water valve, as animal carcasses repeatedly strike the mechanism, it causes substantial wear of the bushings. Moreover, the impeller shaft itself may become bent over time which results in pressure loss or water leaking. Because the water spray lines are rigidly fixed to the water valve they are also often bent by contact from the animal carcasses and they quickly become damaged or inoperable. This necessitates substantial repair and maintenance of the known systems.
Each spray bar is mounted on a rack and is generally connected to a water source at each end. A water valve is used to connect the water source to the water spray bar at each opposing end. Thus, each water bar includes two (2) water valves assemblies. A typical production line usually includes about 20 sprayer bars having 40 total water valves. Because of the extreme wear and tear on the devices, it is necessary to repair or replace these water valves every few months. What is needed is a water valve assembly for use in a packing house that is not easily damaged by the carcasses contacting the spray bars as the carcasses travel along the process line. The instant invention achieves this stated goal by replacing the traditional washer water valve with a very durable manufactured swivel body which includes a ball joint attachment between the swivel body and the spray bar. The swivel body allows the spray bar to move when contacted by animal carcasses thereby limiting damage. Further, the inventive swivel body eliminates the use of set screws, impeller shafts and set collars and is, accordingly, much easier to repair and maintain.
The instant invention is a unique and novel swivel body for a packing house washer. The swivel body is intended to replace the traditional water valves used for packing house water spray devices. The swivel body is manufactured from durable materials such as stainless steel. An inlet into the swivel body is provided through which pressurized water is forced. At one end of the swivel body a pivot ball or ball joint assembly is attached to a waterline coupler. A pair of bushings are mounted adjacent the ball joint to eliminate water leaking as the ball joint articulates within the chamber of the swivel body. A bore through the waterline coupler allows fluid communication with the swivel body chamber. Accordingly, water forced into the swivel body chamber through the inlet then passes into the bore of the waterline coupler and then into a sprayer bar attached thereto. As animal carcasses contact the spray bar the ball joint is articulated, within limits defined by the dimensions of the swivel body chamber, and this movement significantly diminishes the likelihood of damage to the spray bar or the swivel body.
Referring now generally to the drawings, the inventive swivel spray body assembly for use in a packing house spray line is shown and generally referenced by 102. As shown best in
The instant invention is generally limited to the manufacture and assembly of the water valve attached to the spray bar. For purposes of this invention, the term water valve is used interchangeably with the term swivel body. It is well known within the industry that multiple water valves will be used to form a spray rack or spray wall. The detailed description herein, however, is limited to a disclosure of a single water valve with the understanding that each water valve provided in a spray assembly is identical to the exemplar water valve described and disclosed herein. This is in no way intended to limit the scope of the disclosure or the claims appended hereto.
The spray bar is preferably constructed of durable but flexible material such as high density rubber. It is understood that the spray bar can also be manufactured of rigid tube or pipe and from a variety of materials such as galvanized steel, stainless steel or iron and the use of the novel swivel body will achieve substantial and similar improvements over the known devices. The preferred flexible spray bar has several significant advantages. First, the material cost of flexible hose is substantially less than metal piping. Further, the flexibility of the hose material further decreases damage to the spray valve when forcibly contacted by an animal carcass. The flexible hose also is easier to install, repair and replace. In particular, in conjunction with the moveability of the swivel connector of the innovative spray valve, the flexible material is extremely easy to connect.
It is helpful to fully understand the prior art device to appreciate the advantages and improvements of the instant invention. Referring now to
The water valve 202 is generally cylindrical in shape and may be formed from aluminum, hardened steel, stainless steel or other suitable materials. An impeller shaft 216 is mounted longitudinally through the water valve chamber 212. The water impeller shaft 216 also has a bore 220 and at least one opening 218 is provided in the impeller shaft 216 so that water can pass from the water valve chamber 212 into the bore 220 of the impeller shaft 216.
The impeller shaft 216 is longer than the water valve housing 204 and extends beyond the periphery of the water valve 204. At the first end 215 of the impeller shaft 216 a set collar 228 is provided for mounting the device onto a rack or other assembly (not shown). At the second end 217 of the impeller shaft 216 a water line coupler 214 is integrally formed. The water line coupler 214 includes a threaded socket 230 fixed at the second end 217 of the impeller shaft 216 and open at the opposite end for fastening to a spray bar 208.
Because the water valve 202 carries pressurized water, it is necessary to seal the impeller shaft 216 within the water valve chamber 212 to prevent water leaks. Accordingly, a forward bushing 224 is provided on the impeller shaft 216 substantially adjacent the water line coupler 214. A second or rear bushing 222 is provided on the impeller shaft 216 substantially adjacent to the set collar 228. Both the forward bushing 224 and rear bushing 222 are held in place by at least two set screws 226. The bushings are formed from nylon or other suitable material.
During use, when the prior art water valve became damaged, it was necessary to unfasten the set screws 226 to release the bushings 222, 224. Repair generally requires replacement of the impeller shaft 216 and integral water line coupler 214. New bushings are generally installed as a maintenance item. The old bushings may be somewhat difficult to remove and it is particularly difficult to align the bushings such that they can be fastened in place with the set screws. In cases of extreme damage, the water line might have to be cut and then replaced.
Now referring to
As best shown in
The chamber 127 of the swivel body housing 104 is formed such that it has an integral internal sleeve 144. The internal sleeve 144 is integral to the inner wall 146 of the inner body housing 104 and is formed by boring larger diameter water line coupler seats 128 in the chamber 127 at each end of the housing 104. Accordingly, the inner chamber 127 of the swivel body housing 104 has two (2) diameters as best shown in
As best shown in
An internally threaded cap 118 is also mounted on the neck 130 between the water line connector 116 and the ball joint 132. This cap 118 necessarily has an opening 120 through which the neck 130 is positioned. It is preferred that a small race 138 is formed on the inner surface of the cap 118 around the opening 120. A ball joint bushing 136 is placed between the internally threaded cap 118 and the ball joint 132. The race 138 of the threaded cap generally urges the ball joint bushing 136 onto the ball joint 132 as the cap 118 is fastened to the threads 142 of the swivel body housing 104. The opening 120 through the cap 118 is larger in diameter than the neck 130 of the coupler 114. This allows the ball joint 132 of the coupler 114 to articulate within the coupler seat 128 of the housing 104. As the cap 118 is secured onto the threads 142 of the housing 104, the ball joint 132 is captured by the bushings 134, 136 and a water tight seal is formed around the ball joint 132. This eliminates any leakage of water around the coupler 114 to housing 104 connection.
The bore 140 through the water line coupler neck 130 is in fluid communication with the internal chamber 127 of the swivel body housing 104. Thusly, as water is forced through the inlet 110 of the swivel body 102 it is then forcibly passed through the chamber 127 and through the bore 140 of the neck 130 and subsequently into an attached spray bar 108. The ball joint 132 allows the water line coupler 114 to articulate within the swivel body housing 104 to diminish damage to the line 106 and the swivel body 102 when forcibly contacted by animal carcasses.
While the present invention has been described above, it should be clear that many changes and modifications may be made to the device without departing from the spirit and scope of this invention.
This application claims the priority of Ser. No. 61/257,923 filed Nov. 4, 2009 the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20110101133 A1 | May 2011 | US |
Number | Date | Country | |
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61257923 | Nov 2009 | US |