MXPA06011411A - Two handle pull-out faucet - Google Patents

Abstract

A dual handle control faucet (10) that includes a pull out head (28) and a faucet base (12). The pull out head (28) is switchable between a first water discharge pattern and a second water discharge pattern. The pull out head switches from the first water discharge pattern to the second water discharge pattern upon disengagement with the faucet base, which provides for hands-free switching between to two spray patterns.

Description

DISMANTLING FAUCET WITH TWO HANDLES FIELD OF THE INVENTION The present invention relates to a dismantling faucet for faucet, and more particularly, to a faucet for dismantling for faucet with independent control for hot and cold water and a disassembling head that changes between a dew mode and a mode of run when it joins or comes off the tap.

BACKGROUND OF THE INVENTION The faucets are often provided with a disassembly head. The disassembly head allows the user to point the flow of water from the disassembly head to where the flow is useful, and where conventional faucets may not reach. For example, when washing containers and frying pans, the user can disassemble the head and direct the flow to the containers and pans rather than moving the containers and frying pans under the tap. Thus, the disassembly head is much lighter and much easier to remove than the item being washed. The taps with disassembly heads have offered varied output parameters. For this purpose, the outlets have included a flow stop, which is typically an aerator or a spray pattern, which is typically a spray ring or a nozzle array. A commutator or the like, which requires manual operation by the user, is used lpically to change the available output patterns. In addition, the flow conirol is typically adjusted by means of a unique mixing valve rather than cooling valves independent of hot and cold water. Therefore, the disassembly head taps may require the user to manually switch between the spray modes and the use of a single mixing valve to regulate the flow and water temperature. Accordingly, it is desirable to provide a faucet with an improved dismounting head that switches between the outgoing spray pads without requiring the use of a manual switch and which also provides an independent control of the hot and cold water to the tap.

BRIEF DESCRIPTION OF THE INVENTION A double handle control cock is constructed in accordance with the present invention and includes a disassembly head and tap base. The disassembly head is operable between a first water discharge pipe and a second water discharge pipe. The disassembly head changes from the first water discharge pin to the second water discharge pad. The decoupling with the base of the tap, which provides a hands-free change between two spray patterns.

Additional areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiments of the invention, are intended for purposes of illustration only, and are not intended to limit the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be more fully understood from the appended claims, the detailed description and the accompanying drawings of the exemplary embodiments, wherein: Figure 1 is an environmental view of a disassembly faucet having a disassembly head and independent controls of alley and cold water, constructed in accordance with the principles of the present invention; Figure 2 is a top perspective view of the base plate of the tap of the take-off tap of Figure 1; Figure 3 is a perspective view of a central body of the take-off cock of Figure 1; Figure 4 is an exploded perspective view of the components of the disassembly head of the present invention; Figure 5 is a perspective view of a lever of the flow of Figure 4; Figure 6 is a perspective view of an aerator housing of Figure 4; Figure 7 is a perspective view of an assembly of the aerator of Figure 4; Figure 8 is a cross sectional view of the disassembly head in a current mode constructed in accordance with the present invention; Figure 9 is a cross-sectional view of the disassembly head in a spray mode; Figure 10 is an exploded perspective view of the components of the disassembly head constructed in accordance with an alternative embodiment of the present invention; Figure 11 is a perspective view of a flow lever of Figure 10; Figure 12 is a perspective view of a diverter of the Figure 10; Figure 13 is a cross-sectional view of the disassembly head of Figure 10 shown in the current mode; Figure 14 is a cross-sectional view of the disassembly head of Figure 10 shown in the spray mode; Figure 15 is a perspective view of a structure of the lower part constructed in accordance with an alternate embodiment of the present invention; Figure 16 is a detailed view of the structure of the lower part of Figure 15 in a partial cross section; and Figure 17 is an exploded perspective view of an exemplary washbasin assembly consis- tent with an alimentary embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED MODALITIES The following description of the preferred embodiments is merely exemplary in nature and is in no way intended to limit the invention, its application or uses. With reference to Figures 1, 2 and 3, a dismounting cock of the preferred embodiment of the present invention is generally indicated by the reference numeral 10. The dismounting cock 10 includes a base of the faucet 12 to which is connected a spout 14. Tap base 12 includes hot water control 16, and cold water control 18, both of which provide flow regulation and are placed at opposite ends of tap base 12. Tap base 12 also includes a central body 20 in which the fluid flows from the controls of the cold and hot water 16, 18. A cap of the tap 22 provides a decorative cover for the base of the tap 12 and protects the base of the tap 12 from the medium environment in which it was installed. The spout 14 is composed of a rotating base 24 and a neck 26. A disassembly head 28 is configured to be mounted in a reirably manner to the spout 14. The dismantling tap 10 is conventionally moniade to a socket 30 (shown in shading), or at any other suitable location. The conventional moniage of the dismantling tap 10 also includes the connection to a conventional hot water supply line 32 and to a conventional cold water supply line 34. The water heating system 16 also includes a hot water regulator or valve. 36 which is seated in a moniaje body of the conirol of the hot water 38. A connection point of the hot water supply line 40 is connected to the moniaje body of the hot water conirol 38. A copper tube of the hot water 42 connect the moniage body of the water conirol heat 38 to the center body 20. The cold water conirol 18 further includes a cold water regulator or valve 44 which is seated in a monolithic body of the cold water conirol 46. A point of connection of the cold water supply line 48 is connected to the mounting body of the cold water conirol 46. A cold water copper hose 50 connects the body for mounting the cold water control 46 to the central body 20. The central body 20 includes a hot fluid inlet 52, a cold fluid shroud 54, and a mixed fluid outlet 56. The conirol body 20 also includes an orifice for the hose 58. The conirol body 20 is connected to the body of the faucet 12. One skilled in the art will readily appreciate that the center body 20 can be located at several points of the base of the faucet 12 and that it can be secured by various forms of connection .

In a conventional insula- tion, as shown in Figure 1, the dismounting cock 10 is mounted on the upper part of a platform 64 (shown in shading) of the plaque 30. Placed in a central location of the base plate of the tap 60 is the central body 20, of which the copper tube of the hot water 42 and the copper tube of the cold water 50 extend to the control of the hot water 16 and the cold water conirol 18, respectively. The hot water copper pipe 42 is connected to the hot water regulator 36, denier assembly of the hot water condenser body 38. The hot water condenser assembly body 38 is also configured to accept a hot water supply line 32 at the connection point of the hot water supply line 40. Therefore, the hot water regulator 36 controls the flow of hot water in the central body 20, thereby condensing the amount of warm water emitted from the disassembly head 28. The copper tube of the cold water 50 connects to the cold water regulator 44, contained within the cold water control assembly body 46. The cold water con- trol assembly body 46 is also configured to accept a cold water supply line 34 at the connection point of the cold water. the cold water supply line 48. The cold water regulator 44, like the water regulator warm 36, confrole the flow of cold water towards the head of disassembly 28. The base of the tap 12 is mounted to the plate 64 of the plate 30. The mounting body of the running water control 38 and the assembly body of the cold water conirol 46, however, pass through the plate 64 , allowing the hot and cold water supply lines 32, 34 to be connected to the connection points of the hot and cold water supply line 40, 48, respectively, below the plate 64. It will be appreciated by someone With skill in the art, decorative hoods can be used to cover various components of the dismantling tap 10. These hoods can serve to protect the components covered by the hood from the elements inherent in a rail insulation, or can serve the sole function of sííííca aíracción. Someone with skill in the art will readily appreciate that the mounting arrangements of the take-off faucet 10 can take many forms, so that the faucet 10 can be mounted to a conventional line, a thin one for washing, a bath line or any location that requires a regulated water supply. The various locations, therefore, can motivate many possible types of facilities that result in several components mounted above or below the platform of the tarja or similar. Other types of facilities may exclude the tar or playaforma of the tarja. The central body 20 is connected to the copper tube of the hot water 42 and the copper tube of the cold water 50 in the flow of the hot fluid 52 and the cold fluid line 54, respectively. Variable quantities of hot and cold water are mixed within the central body 20 and flow out of the mixed fluid outlet 56. The mixed fluid outlet 56 is connected to a hose 66, which passes through the spout 14 and is connected finally at the head of disassembly 28. Someone skilled in the art will readily appreciate that many configurations of the faucet tap and tap base are possible.; so that the tap base of the preferred embodiment can be connected to many different tap configurations, while the tap spout of the preferred embodiment can be connected to many different configurations of the tap base. The spout 14 includes the rotating base 24 and the neck 26, from which the dismounting head 28 is detached. The dismounting head 28 is attached to the hose 66 which includes a weight 68, threaded connectors 70 and quick disconnect connectors 72 The hose 66 is connected to the mixed fluid outlet 56 of the central body 20 and is then connected to the disassembly head 28. The hose 66 when connected to the mixed fluid outlet 56 is passed through the plaform 64 of FIG. the tab 30, which can provide a hose clearance loop 74 for hanging below the platform 64. The weight 68 is coupled to the hose 66 along a general midpoint of the clearance of the hose 74. The hose 66 can further divided into sections by the threaded connectors 70 or the quick disconnect connectors 72. The use and placement of the weight 68, the threaded connectors 70, and the quick disconnect connectors 72 can be of insol Therefore, the use, placement or exclusion of the weight 68, the threaded connectors 70, and the quick disconnect connectors 72 do not serve to limit the invention or its operability.

The flow of the fluid from the dismantling tap 10 originates with the hot and cold water supplied by the hot and cold water supply lines 32, 34, which are connected to the connection point of the hot water supply line. and to the connection point of the cold water supply line 48, respectively. The hot and cold water flows in the mounting body of the hot water control 38 and the monoling body of the cold water confrol 46, respectively. The water regulator 36 and the cold water regulator 44 regulate the hot and cold water flowing in the central body 20 through the hot fluid 52 and the cool fluid 54 through the copper tube of the liquid. hot water 42 and the copper pipe of cold water 50, respectively. The hot and cold water now mixed leaves the central body 20 through the exit of the mixed fluid 56. The hose 66, connected to the outlet of the mixed fluid 56, transports the water now mixed under the platform 64 of the tarja 30 and then again through the platform 64 as the hose 66 passes through the through hose 58 of the central body 20. The hose 66 continues to transport the mixed water through the spout 14 and connects to the dismantling head 28 in the end of the spout 14. The mixed water is expelled through the dismounting head 28 for use in the base 30 or similar. With reference to Figures 4, 5, 6 and 7, the disassembly head 28 includes a retainer ring 76 which passes through an outer housing 78 for connection to a connector of the hose 82. A spring 80 and a first ring Seals 84 are connected to the hose connector 82. A rubber gasket 86, a retaining nut 88 and a rubber washer 90 are contained within the aerator assembly 92. A second sealing ring 94 is connected to a gasket housing. aerator 96 that connects to the outer housing 78. The hose connector 82 also includes a connection point of the hose 98, which can be connected to the hose 66, using a first threaded portion 100. A second threaded portion 102 connects to the retaining ring 76. A first seat of the sealing ring 104 is configured to accept the first sealing ring 84. A sealing face 106 defines an outlet orifice of the flow 108 which confers a deflection r of flow 110, a lip of flow deflector 112, and spacers 114. Aerator housing 96 further includes an aerator mounting seat 116, a spray ring 118, and a second seal ring seat 120 configured to accept the second sealing ring 94. With reference to Figures 4, 8 and 9, the disassembly head 28 is configured such that a portion of the connector of the hose 82 passes from the interior of the outer housing 78, and was connected to the ring No. 76, which generally sits on top of the bottom housing 78. The ring 76 was connected to the hose connector 82 by rotating the ring 76 on the second threaded portion 102 and also supported the retaining ring 76 as the connector of the hose 82 can move as a unit relative to the previous housing 78. Someone skilled in the art will easily appreciate that there are many other methods for To connect the retaining ring 76 and the connector of the hose 82, one of the exemplary methods is the press fit. Regardless of the manner by which the exiting housing 78 is attached to the registration ring 76, the disassembly head 28 is further configured so that the spring 80 is capped by an annular rim 124 of the outer housing 78 and the connector of the housing. hose 82, when the retaining ring 76 is attached to the connector of the hose 82. The first seat of the sealing ring 104 in the connector of the hose 82, is configured to accept the first sealing ring 84. The first sealing ring seated 84 places and secures the hose connector 82 in the exiting housing 78 and seals the lower extendable housing 78 above the first sealing ring 84. Insertion of the hose connector 82 into the exiting housing 78, therefore, cause the first sealing ring 84 to elapse? In addition, the first sealing ring 84 seals the connector of the hose 82 with the outer housing 78, so that the fluid in the dismantling tap 10 is unable to move further than the outside housing 82. of the first sealing ring 84 in the direction of the retaining ring 76. The rubber junction 86 is configured to settle within a lower ring 122 of the locking nut 88.; thus, when it is seated to the rubber juniper 86 and the fastening nut 88, it is essentially a moniage. When the clamping nut 88 is rotated to secure the moniage of the aerator 92 in the aerator housing 96, the rubber gasket 86 can rotate with the clamping nut 88. However, the rubber rod 86 remains operable in any orientation Angular, even if it rotates with the clamping nut 88. When the clamping nut 88 is rotated on the monache of the aerator 92, the clamping nut 88 secures the rubber washer 90 with the assembly of the aerator 92; thus securing the rubber washer 90 as the aerator monaire 92 in the aerator housing 96. The hose connector 82 includes the sealing face 106 which defines the outlet orifice of the flow 108. The flow deflector 110 and the The flow deflector lip 112 extends from the outlet orifice 108 through the use of spacers 114. The sealing face 106 includes an annular arcuate portion 126 and within the annular arcuate portion 126 is the exit orifice of the flow 108. Hose connector 82, therefore, has an internal channel 128 running from the point of the connector of the hose 98 to the exit orifice of the flow 108. The deflector of the flow 110 extends from the exit orifice of the flow 108, which contains a lip of the flow deflector 112. The flow deflector 110 is positioned above the outlet outlet of the flow 108 by four spacers 114. With the hose connector 82 connected with the retaining ring 76 and the assembly of the aerator 92 secured within the housing of the aerator 96, the ex- terior housing can be secured to the aerator housing 96 to finally mount the dismounting head 28. The aerator housing 96 is configured to accept the second seal ring 94. , so that when the outer housing 78 is rotated to join the housing of the aerator 96, the second sealing ring 94 is compressed between the outer housing 78 and the housing of the aerator 96. The compression of the second sealing ring 94 prevents the Fluid comes out of the disassembly head 28 of the area where the outer housing 78 and the aerator housing 96 are connected. In Figure 8, the disassembly head 28 is presented in a current mode, which is generally indicated by the reference number 132. In Figure 9, the disassembly head 28 was presented in a dew mode, which is indicated generally by reference numeral 130. The change between the dew mode 130 and the current mode 132 is effected by the movement of the hose connector 82, so that when the connector of the hose 82 is moved to the lowermost point of the hose. its displacement results in the disassembly head 28 entering the current mode 32. In turn, moving the hose connector to the uppermost point of its displacement results in the disassembly head 28 entering the mode of dew 130. In dew mode 130, the hose connector 82 is at the most superior point of its displacement, so that the lip of the flow deflector 112 of the flow deflector 110 has been moved up and sealed against board 86. Sealing the lip of the flow deflector 112 against the rubber gasket 86 prevented the fluid from continuing beyond the rubber gasket 86, thereby forcing the fluid to flow on and beyond the excerpt of the nut. of clamping 88. As indicated by the arrow indicating flow 134, the fluid continues in an annular channel 136 and then is finally emitted from a dew ring 118. In the preferred embodiment of the present invention, the dew ring contains 16 rectangular openings 142 with dimensions of approximately 1,016 millimeters (0.04 inches) to approximately 1.27 millimeters (0.05 inches). The fluid leaves the rectangular openings 142 in dew columns which are sensed individually when compared to the flow column of the aerator assembly 92. One skilled in the art will readily appreciate that the rectangular openings 142 may have various dimensions. For this end, the rectangular openings 142 may be circular openings or any other suitable geometric shape. In addition, the dimensions can be of any suitable configuration to produce flows of the dew ring 118. In the current mode 132, the connector of the hose 82 is at the lowest point of its displacement, so that the sealing face 106 and the annular arcuate portion 126 is sealed against the rubber gasket 86. When sealed, the flow baffle 110 is placed below the rubber gasket 86, so that the fluid is forced to flow out of the flow exit orifice. 108 and in the assembly of the aerator 92. For this purpose, the fluid is unable to flow past where the annular arcuate portion 126 has been sealed against the rubber junction 86, which prevented any fluid from flowing through the ring. dew 118. Therefore, the fluid flowing from the dismantling head 28 in the current mode 132 flows only through the assembly of the aerator 92 in a current outlet. In the preferred embodiment of the present invention, the aerator assembly 92 is commercially available from Neoperl, Inc. (Waferbury, CT), under the name of the Perlaor model. The fluid leaves the assembly of the aerator 92 in a large column and lacks individual perceived currents when compared to the water coming out of the dew ring 18 when the disassembly head 28 is in the dew mode 130. Someone with experience in the Technique will appreciate that the final pattern produced can vary with the modification of the aerator mona 92 or the spray ring 118. The change between the dew mode 130 and the run mode 132 can be effected by the attachment or detachment of the disassembly head. 28 of the end of the neck 26 of the spout 14. When the dismounting head 28 is attached to the spout 14, the dismounting head 28 remains in the current mode 132 because the neck end 26 has pushed the retaining ring 76 and therefore, the connector of the hose 82 down towards the lowest point of its displacement. In Figure 8, the disassembly head 28 is shown in the current mode 132 and, therefore, the spring 80 is configured to be in a rest condition 138. In Figure 9, the disassembly head is shown in FIG. the dew mode 130 and, therefore, the spring 80 is configured to run in a compressed condition 140. Therefore, it turns out that the movement of the spring 80 from the rest position 138 (FIG. 8) to the compressed condition 140 (Figure 9) generates a spring force in the spring 80; so that the spring 80 imparts a predetermined force in an attempt to return to its rest position 138. The disassembly head 28, however, is configured to remain in the dew mode 130 times that water or a similar fluid flows through the disassembly head 28. The fluid flowing through the disassembly head 28 in the dew mode 130, thereby, imparts sufficient pressure to the sealing face 106 to keep the disassembly head 28 in place. the dew mode 130. Therefore, when the fluid flow is interrupted, the spring force imparted by the spring 80 in the compressed condition 140 is sufficient to reset the disassembly head 28 to the run mode 132. In addition, the spring force imparted by the spring 80 in the compressed condition 140 is less than the pressure exerted on the sealing face 106 of the hose connector 28 in the dew mode 130. Typically When the dismounting head 28 is attached to the neck 26, the dismounting head remains in the running mode 132. When a user (unmasked) desires to detach the dismounting head 28 from the neck 26, the user can hold the housing. exterior 78 or the housing of the aerator 96 and pull the dismounting head 28 away from the neck 26 and manipulate the head accordingly. As the user pulls the dismounting head 28 away from the neck 26, the hose 66, the weight 68, and the neck 26 are configured to lightly restrain the dismounting head 28, so that the action of pulling the dismounting head 28 of the neck 26 causes the dismounting head 28 to change from the run mode 132 to the dew mode 130. As indicated above, if the fluid is flowing through the dismounting head 28, the head 28 will remain in the dew mode 130 If no fluid is flowing through the head, the dismounting head 28 will return to the current mode 132 when the force generated by the action of pulling the disassembly head 28 of the neck 26 no longer exists. In addition, the disassembly head 28 can be pulled from the neck 26 while the fluid flows through the dismounting head 28, but the user can interrupt the flow of fluid through the dismounting head 28 by hearing things, closing the head. faucet 10. When the fluid flow is interrupted, the disassembly head 28 returns to the current mode 132. No matter if the dismounting head 28 is attached or detached to the neck 26 or the fluid is flowing through the head of the head 26. Disassembly 28, the user can manually push or pull the retention ring 76 to manually change the dismounting head 28 to the dew mode 130 and the run mode 132. A user can also detach the dismounting head 28 of the neck 26 of the tap 10, but holding the retaining ring 76 in place of the outer housing 78 or the housing of the aerator 96 of the disassembly head 28. By doing this, the dismounting head 28 is prevented from changing to the mode of spray 130. The user can subsequently fasten the sensing ring 76 and pull it to change the dismounting head 28 of the run mode 132 to the spray mode 130. It will be appreciated by someone skilled in the art that the retainer ring 76 can It may take many forms or it may not be included with the dismantle tap 10. For example, the ring 76 may be in the form of a knob or collar attached to the hose 66 or any of a head control mechanism that helps the head. user to change between the dew patterns of the disassembly head 28. For the sake of it, someone with experience in the technique will also appreciate that the dew mode 130 and the mode of running 132 or the Exemplary spray pads and dismantling head 28 can be configured with alternate spray pattern configurations. Figures 10 to 14 describe the disassembly head 28 constructed in accordance with a preferred alternate embodiment of the present invention. Therefore, reference numbers describing similar structures can be used to denote common expressions to the various modalities. It should be appreciated by someone skilled in the art that the structures described in any modality can be interchangeable with other modalities. It should also be appreciated that the described embodiments of the present invention are descriptive in nature and do not serve to limit the invention to the embodiments described.

With reference to Figures 10, 11 and 12, the disassembly head 28 includes a part of the upper housing 200 which is connected to a part of the lower housing 202 and hereinafter referred to collectively as the housing 204. A flow lever 208 is contained within the housing 204 and includes a threaded portion 236 that can be connected to the hose 66, which passes through the upper housing 200. A spring 206 is contained between the flow lever 208 and the upper housing 200. The lever of flow 208 includes positioning lugs 238 and a seal seat of the flow lever 210 in which the seal of the flow lever 212 is seated. The flow lever 208 further includes a flow conduit 214, a seat of the upper junction of the flow conduit 216, and an inlet of the lower junction of the flow conduit 218. An upper seal of the flow conduit 220 sits in the upper flow-seal seat 216 and a lower flow-flow condyle juniper 222 sit in the lower seal seat of the flow conduit 218. The flow conduit 214 of the flow lever 208 is configured to oscillating through a central opening 224 defined by a diverter 226. The diverter 226 further defines an annular plurality of openings 228 positioned around the central aperture 224. It should be noted that the central aperture 224 is not fluidly connected to the annular plurality. of openings 228 and vice versa. In addition, the diverter 226 is connected to the lower housing part 202 and is secured in place when the lower housing part 202 is connected to the upper housing 200. Secured between the diverter 226 and the lower housing 202 is a dew ring 230. A flow screen 232 is contained within the dew ring 230. A gasket of the flow pan 234 is placed between the deviator 226 and the flow screen 232. Therefore, the deviator 232 secures the screen gasket. of flow 234, the flow screen 232, and the dew ring 230 in the lower housing part, when the upper housing part 200 is secured to the lower housing part 202. The diverter 226 can be configured to enter into a contacted the junction of the flow screen 234 so that when the water flows through the central opening 224 of the diverter 226, the seal of the flow pan 232 can prevent the water from moving through the dew ring 230. In turn, when the water flows through the annular plurality of openings 228 of the diverter 226, the shield seal flow 234 can prevent water from moving through flow screen 232. Upper housing 200 can be configured to contain spring 206 between flanges 240 and an outer face 242 of the flow lever seal seat 210. The retaining lugs 238 can be configured to maintain the position of the flow lever 208 within the upper housing 200. The upper housing 200 can further be configured to be connected to the lower housing 202 with conventional screw threads. Someone with experience in the art will easily appreciate that there are many methods to monitor the accommodation.; Some of these examples include pressure adjustments, joining or mechanical fasteners. With reference to Figures 13 and 14, the disassembly head 28 was presented in a current mode (Figure 13), indicated generally by the reference number 132 and in a dew mode (Figure 14), indicated generally by the number reference 130. The movement of the flow lever 208 results in the movement of the flow conduit 214 in and out of the central opening 224 of the diverter 226. When the disassembly head 28 is in the run mode 132, the control lever The flow 208 reaches the bottom of its movement within the housing 204. In the current mode 132, the upper junction of the flow conduit 220 vents and seals the central opening 224 of the diverter 226. When the disassembly head 28 is in the mode of dew 130, the flow lever 208 reaches the top of its movement. In the dew mode 130, the lower seam of the flow conduit 222 is sealed within the central opening 224, thereby placing the flow conduit 214 on top of the seam of the central aperture 224. In the current mode 132, the upper seal of the flow conduit 220 has entered into, and sealed the central opening 224. Therefore, the conduit of the flow 214 expels the water below the now sealed central opening 224. Because the upper seal of the conduit Flow 220 has sealed the central opening 224 above the flow conduit 214, the water expelled from the flow conduit 214 can exit only through the flow pan 232 of the disassembly head 28.

In the dew mode 130, the lower juniye of the flow conduit 222 has sealed the central opening 224. Because the central opening 224 has been sealed, the water flowing out of the flow conduit 214 must flow through the plurality. annular of openings 228 of diverter 226. Water flowing through annular plurality of openings 228 then flows through dew ring 230. One skilled in the art will readily appreciate that flow screen 232 is a pan of the aerator conventional modified, which causes water to flow from the disassembly head 28 into a generally uniform column. The dew ring 230, in conírasie, causes the water to be sprayed in a paírón generally in cone form, where the individual currents of water can be recognized. One skilled in the art will also appreciate that the final produced payroll can be varied with a modification of the flow screen 232 or the dew ring 230. Therefore, the path of the water flow is determined by the movement of the lever. flow 208 through diverter 226; Regardless of this fact, the final tap of the produced water can be varied, made the same or even eliminated or sealed, where no water would flow. The change between the current mode 132 and the dew mode 130 can be effected by the connection or detachment of the dismantling head 28 at the end of the neck 26 of the spout 14. With the disassembly head 28 attached to the spout 14, the disassembly head 28 remains in the current mode 132 because the end of the neck 26 has pushed the flow lever 208 down to the lowest point of its displacement. With the flow lever 208 downward at the lowermost point of its displacement, the flow conduit 214 discharges the water below the central opening 224 of the diverter 226 and the water is supplied in the current mode 132. In the Figure 13, the disassembly head 28 is shown in the current mode 132 and, as such, the spring 206 is configured to be in an idle condition 138. In Figure 15, the disassembly head is shown in the dew mode 130 and, therefore, the spring 206 is configured to be in a compressed condition 140. Therefore, it turns out that the movement of the spring 206 from the rest position 138 (Figure 13) to the compressed condition 140 (Figure 14) , generates a spring force in spring 206; so that spring 206 imparts a predetermined force in an attempt to return to its rest position 138. Disassembly head 28, however, is configured to remain in dew mode 130, while water or a similar fluid flows through the disassembly head 28. The fluid flowing through the disassembly head 28 in the dew mode 130, imparts sufficient pressure at the bottom face 244 of the flow lever 208 to maintain the head of the head. disassembly 28 in the dew mode 130. Therefore, when the fluid flow is interrupted, the spring force imparted by the spring 206 in the compressed condition 140 is sufficient to reset the disengagement head 28 to the mode of flow 132.

Typically, when the dismounting head 28 is attached to the neck 26, the dismounting head remains in the current mode 132. When a user (non-mosdy) desires to detach the dismounting head 28 from the neck 26, the user can hold the housing 204 and pull the disassembly head 28 away from the neck 26 and manipulate the head accordingly. As the user pulls the dismounting head 28 away from the neck 26, the hose 66, the weight 68, and the neck 26 are configured to lightly resist the stripping head 28, so that the action of pulling the stripping head 28 off of the neck 26, causes the dismounting head 28 to change from the run mode 132 to the dew mode 130. As indicated above, if a fluid is flowing through the disassembly head 28, the head 28 will remain in the dew mode 130. If no fluid is flowing through the head, the dismount head 28 is configured to return to the current mode 132 when the force generated by the action of pulling the disassembly head 28 of the neck 26 no longer exists. In addition, the dismounting head 28 can be pulled from the neck 26 while the fluid flows through the dismounting head 28, but the user can, consequently, interrupt the flow of fluid through the dismounting head 28 by, between other things, closing the tap 10. When the fluid flow is interrupted, the dismounting head 28 returns to the current mode 132. Figures 15 and 16 describe the tap 10 constructed in accordance with a preferred alternate embodiment of the present invention. Therefore, reference numbers describing similar structures can be used to denote structures common to the various modalities. It should be appreciated by someone skilled in the art that the structures described in any modality can be interchangeable with other modalities. It should also be appreciated that the described embodiments of the present invention are descriptive in nature and do not serve to limit the invention to the described embodiments. With reference to Figures 15 and 16, an assembly of the bottom part is generally indicated with the reference numeral 300. The bottom part 300 is a singular cast component, which may include components found in the base of the tap 12. For this purpose, the lower part assembly 300 is configured to include the hot water control assembly body 38 and the connection point of the hot water supply line 40. The lower part 300 assembly also includes the the cold water conirol 46 moni- tor body and the connection point of the hot water supply line 48. In conifers with the cold water copper tube 50, the central body 20, and the hot water copper tube 42 , the moniaje of the lower part 300 is consumed as a singular unit. In the meantime, a connecting member 302, connected the moniage body of the cold water conirol 46 and the mounting body of the hot water confrol 38. A moniaje collar 304 is connected to the connecting member 302. The moniaje collar It is configured to be connected to the spout 14 and is further configured to serve as a fluid connection between the connecting member 302 and the spout 14. The mounting collar 304 further defines a tubular rod channel 306 through which a rod passes. Tubular 308 (Figure 17). A vacuum interrupter seat 310 is configured to accept a vacuum interrupter 312 (Figure 17). It should be appreciated by one skilled in the art that the vacuum interrupter can be located at various points within the faucet 10. As shown, the vacuum interrupter 312 is located in the assembly of the lower part 300, but can be located in the bodies of the hot or cold water control assembly 38, 46 or in other suitable locations. Similar to the central body 20, the lower part assembly includes a hole for the hose 58, which is placed in a central location in the lower part 300. The through-hose 58 is slightly inclined to accommodate the geometry of the mounting. the bottom 300, but still allow the hose 66 to pass through the hole for the hose to pass 58 unimpeded. The output of the mixed fluid 56 is configured to be connected to the hose 66 (Figure 1). Figure 17 describes the tap 10 presented in a lavatory configuration and constructed in accordance with a preferred alimentary mode of the present invention. Therefore, reference numbers describing similar features can be used to denote common expressions to the various modalities. It should be appreciated by someone skilled in the art that the structures described in any modalities can be interchangeable with other modalities. It should also be appreciated that the described embodiments of the present invention are descriptive in nature and do not serve to limit the invention to the embodiments described. Although there are many similar structures in a sink installation when compared to a kitchen installation, a frequent difference in the configuration is the distance between the connection point of the hot water supply line 40 and the connection point of the cold water supply line 48. In a typical sink installation, this distance is four inches (approximately 100 millimeters), but in a kitchen installation, this distance is approximately eight inches (approximately 203 millimeters). Regardless of typical installations, some tap configurations only have a single water configuration that would not require separation beforehand. To that end, many configurations are possible and it is also possible to improve the components of a kitchen installation to a sink to make the tap 10, regardless of the installation, more fuel for the consumer. The description of the invention is of merely exemplary nature and therefore, the variations that do not deviate from the essence of the invention, are intended to be within the scope of the invention. Such variations should not be considered as departing from the spirit and scope of the invention.

Claims (20)

NOVELTY OF THE INVENTION CLAIMS

1. - A tap comprising: a disassembly head and a tap base, the dismantling head changes in front of a first water discharge pipe and a second water discharge pipe, where the disassembly head changes from the first discharge pattern of water to the second water discharge pattern after decoupling with the base of the tap.

2. The faucet according to claim 1, further characterized in that the first water discharge pattern includes a current mode and the second water discharge pattern includes a dew mode.

3. The tap according to claim 1, further characterized in that it comprises a control of the hot water and a control of the cold water that are fluidly connected to one of a central body and one assembly of the lower part.

4. The tap according to claim 3, further characterized in that the control of the hot water includes an inaccurate position, a positive position and a plurality of positions between the inactivated position and the activated position.

5. The tap according to claim 3, further characterized in that the cold water control includes an inactivated position, an activated position and a plurality of positions between the inactivated position and the activated position.

6. The tap according to claim 3, further characterized in that a passage of the hot water connects the control of hot water to the central body, and where a cold water passage fluidly connects the cold water control with the body central.

7. A faucet for faucet comprising: a faucet base adapted to be mounted on a platform of a faucet, the faucet base includes a mounting of the lower part that has at least one supply opening fluidly coupled to a body of mixing through a supply valve and spigot; a hose slidably mountable from the spout, the hose having a first extrude fluidly coupled to the mixing body; and a disassembly head fluidly coupled to a second hose outlet, the dismounting head is positionable in a stored position to couple the spout, so that a mode valve on the dismounting head operates in a current mode through a current opening and in an extended position to decouple the spout, so that the mode valve operates in a spray mode through a spray and an opening.

8. The faucet for table according to claim 7, further characterized in that the base for the faucet comprises a first supply opening fluidly coupled to the mixing body through a first supply valve and a second supply opening fluidly coupled to the mixing body through a second supply valve.

9. The faucet for table according to claim 7, further characterized in that the mode valve comprises a flow lever coupled to the hose and a diverter positionably slidable relative to the flow lever to change the valve mode between the current mode and the dew mode.

10. The faucet for table according to claim 9, further characterized in that the flow lever has a radial flow conduit formed therein, and the derailleur has a central opening formed therein, the derailleur is positionable so slidable relative to the flow lever between a first position, wherein the radial flow conduit is in fluid communication with the flow opening and a second position, wherein the radial flow conduit is in fluid communication with the spray opening .

11. The card tap according to claim 10, further characterized in that it comprises a spring placed operably on the disassembly head to impart a deflection force on the diverter towards the first deflection.

12. The faucet for the table according to claim 11, further characterized in that the diverter has a sealing face formed therein, the sealing face is in fluid communication with the radial flow conduit when the mode valve is in the dew mode, so that a fluid pressure exerted On the sealing side, the diverting force to keep the valve mode in a dew mode.

13. The faucet for table according to claim 7, further characterized in that the disassembly head comprises: a first flow of the hose from the valve mode to an aerator placed centrally in the head of disassembly to provide the current mode; and a second flow of the hose from the valve to a set of openings placed around the aerator to provide the dew mode.

14. The faucet for table according to claim 13, further characterized in that the mode valve comprises a flow lever coupled to the hose and a diverter slidable with respect to the flow lever, the derailleur is positionable in a first position to select the first flow path and a second position to select the second flow path.

15. The faucet for table according to claim 14, further characterized in that the flow lever has a radial flow conduit and the diverter has a central opening formed therein, wherein a portion of the flow lever is placed below the central opening, so that the first flow path is defined from the radial flow condiment to the opening of the stream when the diverter is in a first position, and where the radial flow conduit is placed above the opening. central, so that the second flow path is defined from the radial flow conduit to the spray opening when the diverter is in the second position.

16. The faucet for table according to claim 15, further characterized in that it comprises a spring operably placed in the disassembly head, to impart a deflection force in the diverter to the first position.

17. The faucet for table according to claim 16, further characterized in that the diverter has a sealing face formed therein, the sealing face is in fluid communication with the radial flow conduit when the deviator is in the second position, so that a fluid pressure exerted on the sealing face counteracts the deflection force to maintain the mode valve in the dew mode.

18. A disassembly head for a tap comprising: a housing; a hose connector slidably supported in the housing, the hose connector has a passage formed through and terminating in a flow deflector having a radial flow conduit formed therein; a diverter having an opening, a first opening and a second opening formed therein, the diverter is supported in a fixed manner in the housing so that the connector of the hose is positionable between a first position where the flow deflector is extends through the opening and a second position where the flow deflector seals the opening; a spring interposed between the housing and the connector of the hose to impart a deflection force in the conecfor of the hose to the first position; wherein a first flow fray is defined by the passage, the radial flow conduit and the first opening to provide a first discharge mode when the conecfor of the hose is in the first position; and wherein a second stream of flow is defined by the passage, the conduction of the radial flow and the second opening to provide a second discharge mode when the hose connector is in the second position.

19. The disassembly head according to claim 18, further characterized in that the diverter has a sealing face formed therein, the sealing face is in fluid communication with the radial flow conduit when the hose connector is in the second position, so that a fluid pressure exerted on the sealing face counteracts the deflection forces to maintain the hose connector in the second position.

20. A tap comprising: a disassembly head connected to a tap base, the disassembly head includes a flow lever and a diverter; the diverter includes a first flow path and a second flow path; the flow lever changes between a first position and a second position, wherein the first position directs a fluid through the first flow path, and the second position directs a fluid through a second flow path, wherein the Uncoupling the dismounting head from the tap base changes the flow lever from the first position to the second position. SUMMARY OF THE INVENTION A double-handled control cock that includes a disassembly head and tap base; the disassembly head changes between a first water discharge pattern and a second water discharge pin; The disassembly head changes from the first water discharge pattern to the second water discharge pattern after uncoupling with the tap base, which provides hands-free switching between two dew patterns. 29B P06 / 1743F Fig. 5