1. Field of the Invention
The present invention relates to a water dispensing device capable of recycling cold water that can be applied in shower equipment to recycle and reuse cold water in the pipes.
2. Description of the Prior Art
Many conventional watering devices, especially in shower equipment, are operated by manual labor or electrical pressing method to adjust a mixing valve for mixing the hot and cold waters together at a proper proportion and then the water will be sprayed outward through body jet, handheld showerhead and overhead showerhead, etc.
However, some hot water will leave in flowing pipes of a heater and a mixing valve. After a period of time, the left hot water become cold and be sprayed outward after user turns on the mixing valve once more, but such cold water do not reach an appropriate high temperature, according it will be flowed away but not to be used, causing a source consumption.
The present invention has arisen to mitigate and/or obviate the afore-described disadvantages.
The primary object of the present invention is to provide a water dispensing device capable of recycling cold water which is capable of overcoming the shortcomings of the conventional water dispensing device.
A water dispensing device capable of recycling cold water in accordance with the present invention comprises:
a mixing valve connected with a first pipe for supplying cold water and a second pipe for supplying hot water and being turned on/off so that the cold and the hot waters can be mixed at a proper proportion to be outputted;
at least one watering member connected with an output end of the mixing valve;
a bucket connected with the output end of the mixing valve and the first pipe to store water from the mixing valve, and as the mixing valve is opened and the water in the bucket reaches a predetermined condition, the water in the bucket forms low-pressure cold water to be supplied to the first pipe so as to completely or partially replace high-pressure cold water; as the water in the bucket recovers but not reach a predetermined condition, the low-pressure cold water is stopped to be supplied, recovering normal supply of the high-pressure cold water.
a control unit being used to sense a temperature of the water flow which passes through the mixing valve, as a sensed temperature is less than a water flowing set value, the cold water stored in a pipe system will be guided to recycle toward the bucket and then to be supplied to the first pipe, obtaining recycling and reusing purpose, while the sensed temperature is more than the water flowing set value, the cold water stored in the pipe system will be guided to flow toward the watering members;
wherein the control unit further comprises:
a diverter disposed to first flowing pipes between the output end of the mixing valve and the watering members and to second flowing pipes between the output end of the mixing valve and an input end of the bucket to be controlled appropriately;
a temperature sensor serving as sensing a temperature of water flow which passes through the mixing valve, as the temperature is lower than a set value, the diverter communicates the output end of the mixing valve with the bucket, and a flowing pipe between the mixing valve and the watering members is closed so that cold water stored in the pipe can be guided to be recycled toward the bucket, yet as the temperature is higher than the set value, the diverter communicates the output end of the mixing valve with the watering members, and the flowing pipe between the mixing valve and the bucket is closed so that cold water stored in the pipe can be guided to the watering members.
The water dispensing device capable of recycling cold water further comprises a pressure on-off valve connected with the first pipe and an output end of the bucket and allowing to be in an open state as the mixing valve is actuated, and as the water in the bucket is over a predetermined pressure, the output end of the bucket communicates with the first pipe, and the first pipe between the high-pressure cold water and the mixing valve is closed so that the low-pressure cold water from the bucket is guided to the first pipe; and as the pressure of the bucket is lower than the predetermined pressure, the output end of the bucket and the first pipe are closed, and the first pipe between the high-pressure cold water and the mixing valve is communicated to recover a supply of high-pressure cold water.
a is a block diagram showing circuit of the water dispensing device capable of recycling cold water in accordance with the first embodiment of the present invention;
The present invention will be clearer from the following description when viewed together with the accompanying drawings, which show, for purpose of illustrations only, the preferred embodiment in accordance with the present invention.
Referring to
The mixing valve 10 is connected with a first pipe 1 for supplying cold water and a second pipe 2 for supplying hot water and is turned on/off so that the cold and the hot waters can be mixed at a proper proportion to be outputted.
Each of the watering members 20 is connected with an output end of the mixing valve 10 so that the water in watering member 20 can be expelled selectively via the mixing valve 10. The watering member 20 is selected from body jet, handheld showerhead, and overhead showerhead.
The bucket 30 is coupled with the output end of the mixing valve 10 and the first pipe 1.
The control unit a is used to sense a temperature of the water flow which passes through the mixing valve 10, as a sensed temperature is less than a water flowing set value, the cold water stored in a pipe system will be guided to recycle to the bucket 30 and then to be supplied to the first pipe, obtaining recycling and reusing purpose, while the sensed temperature is more than the water flowing set value, the cold water stored in the pipe system will be guided to flow to the watering members 20; wherein
a diverter 40 is disposed to first flowing pipes between the output end of the mixing valve 10 and the watering members 20 and to second flowing pipes between the output end of the mixing valve 10 and an input end of the bucket 30 to be controlled appropriately. The mixing valve 10 is coupled with one of the watering members 20 or the bucket 30 alternatively; the diverter 40 further includes a first solenoid valve 41 and three second solenoid valves 42;
the first solenoid valves 41 is fixed to a water pipe between the mixing valve 10 and the bucket 30 and can be closed in a normal status, as the first solenoid valves 41 is opened, the output end of the mixing valve 10 communicates with the bucket 30;
the second solenoid valves 42 are mounted to another water pipe between the mixing valve 10 and the watering members 20 respectively and can be closed in a normal status; wherein any of the second solenoid valves 42 can be opened by user so that the output end of the mixing valve 10 and the watering members 20 in response to the second solenoid valves 42 are communicated with each other.
A temperature sensor 50 serves as sensing the temperature of water flow which passes through the mixing valve 10. As the temperature is lower than a set value for watering requirement, the first solenoid valve 41 of the diverter 40 is opened, yet as the temperature is higher than the set value, the second solenoid valves 42 of the diverter 40 are opened.
The pressure on-off valve 60 as shown in
a valve base 61 being provided with an inlet 611 for inflowing high-pressure cold water, an outlet 612, a low-pressure cold water intake 613 for inflowing low-pressure cold water, and an inner chamber 614; the valve base 61 including a first valve member 61a and a second valve member 61b, both of which are screwed with each other, and a third valve member 61c; the first valve member 61a including one part of the inlet 611, the outlet 612, and the inner chamber 614; the second valve member 61b is formed a main part of the inner chamber 614; the third valve chamber 61c is formed the low-pressure cold water intake 613.
A first valve core 62 is defined in the inner chamber 614 of the valve base 61 and resiliently biased rearward so that a seal washer 621 which is fixed on a front end keeps away from a high-pressure cold water passage 622 between the inlet 611 and the outlet 612, such that the high-pressure cold water passage 622 keeps in a communicating state. As the pressure of low-pressure cold water is more than a predetermined pressure, the first valve core 62 is pushed forward so that the high-pressure cold water passage 622 is closed by the seal washer 621 as illustrated in
A first resilient element 63 is a compression spring so that the first valve core 62 is resiliently biased rearward, such that the seal washer 621 keeps away from the high-pressure cold water passage 622, and the high-pressure cold water passage 622 keeps in a communicating state, thereby the first valve core 62 still owns elasticity to returns its initial positions.
A second valve core 64 is defined on a rear end portion of the low-pressure cold water passage 623 and is elastically abutted rearward to close the low-pressure cold water passage 623 between the low-pressure cold water intake 613 and the outlet 612. While the pressure of the low-pressure cold water is over a predetermined pressure, the second valve core 64 is pushed forward to be opened so that the low-pressure cold water passage 623 is opened as shown in
A second resilient element 65, which is a compression spring in this embodiment of the present invention, is used to push the second valve core 64 to move rearward so as to close the low-pressure cold water passage 623 normally, such that the second valve core 64 owns elasticity to return its original position.
The water dispensing device of the first embodiment of the present invention is applied in a digital shower system, therefore the mixing valve 10 is used a digital control valve such that a digital controller module 3 drives the mixing valve 10 by using a motor 4, wherein the digital controller module 3 includes an internal controller 3a with a central processor (not shown) and a liquid crystal display 3b. Of course, an external controller 3c can be used to control the liquid crystal display 3b. A user can apply the internal controller 3a or the external controller 3c to set various operations and display a variety of numeral values and states and the like massages, the internal controller 3a can be used to receive and process detected signals from the temperature sensor 50 so as to turn on/off and control the first and second 5 solenoid valves 41, 42 of the diverter 40. Because the digital operation mode is well known, further remarks will be omitted.
Referring to
As above description, the water stored in the bucket 30 can be guided into the first pipe 1 in water supplying operation, therefore as the user turns on the water dispensing device once more, the temperature sensor 50 senses the temperature of water flow of the mixing valve 10 and the cold water recycling and supplying is under process. As the user turns on the mixing value 10 to outflow water, the pressure in the bucket 30 reaches a predetermined value so that the pressure resists against the elasticity of the first and second resilient elements 63, 65 by communicating water flow pressure via the low-pressure cold water intake 613 of the pressure on-off valve 60, thereby actuating the first and second valve cores 62, 64. Thereafter, the high-pressure cold water passage 622 is closed and the lower-pressure cold water passage 623 is opened as shown in
As illustrated in
The water dispensing devices of the first and second embodiments of the present invention are designed to a digital control valve but also can be a manually mechanical type. However, the mixing valve 10 of the water dispensing device of the first embodiment is driven by the motor 4 and the detected signal of the temperature sensor 50 is transmitted to the digital controller module 3 or the controller 5 so as to control the diverter 40. However, the mixing valve 10 of the water dispensing device of the second embodiment is a mechanical control valve operated by manual labor, and the temperature sensor 50 is used to directly control the diverter 40, hence the mixing valve 10 of the present invention can be used in a digital or mechanical control valve type.
To comply with safety regulations, the bucket 30 can cooperate with a release valve (not shown) to approach some predetermined conditions, thus releasing water in the bucket properly, wherein the release valve can be installed to the bucket 30 independently or coupled to the pipes between the bucket 30 and the first solenoid valve 41. The predetermined condition is a predetermined level or pressure.
Except for the sole bucket 30, a plurality of tubular containers (not shown), which are joined together by using their upper and lower ends, are arranged in an appropriate manner to assemble another bucket, and the upper and lower ends of the tubular containers are in communication with each other by using at least one offset tube, such that the pressure value of each of the tubular containers is smaller than that of the sole bucket, enhancing the safe coefficient of the bucket to bear pressure. Furthermore, as receiving space is limited, the bucket formed of the tubular containers can also be arranged in the limited space by changing the number of the tubular containers.
The pressure on-off valves 60 of the water dispensing device according to the first and second embodiments of the present invention are a sole valve but not be limited in the sole valve type. As shown in
the pressure valve 701 further includes a valve base 71, a valve core 72, and a resilient element 73, the valve base 71 includes a high-pressure cold water inlet 711 for inputting the high-pressure cold water, a cold water outlet 712, a low-pressure cold water intake 713 for inputting low-pressure cold water, and an inner chamber 714, all of which are in communication with each other. The valve core 72 is defined in the inner chamber 714 of the valve base 71 and is pushed by the resilient element 73 to move rearward so that a seal washer 721 on a front end of the valve core 72 keeps away from a high-pressure cold water passage 715 between the high-pressure cold water inlet 711 and a high-pressure cold water passage 715, thereby keeping the high-pressure cold water passage 715 in an open state. As the pressure of the valve core 72 from the lower-pressure cold water of the low-pressure cold water intake 713 is over a predetermined pressure, the valve core 72 can resist against the resilient element 73 to move forward and close the high-pressure cold water passage 715 as shown in
The first check valve 702 includes a low-pressure cold water port 74 and a cold water opening 75, the low-pressure cold water port 74 communicates with the low-pressure cold water passage 741 between the output end of the bucket 30 and the low-pressure cold water intake 713. The cold water opening 75 can be in communication with the first pipe 1 between the cold water outlet 712 of the pressure valve 701 and an input end of the mixing valve 10.
The second check valve 703 includes a cold-water inflowing bore 76 and a cold-water outflowing hole 77, the cold-water inflowing bore 76 communicates with the cold water outlet 712 of the pressure valve 701 via the first pipe 1 and the cold water opening 75 of the first check valve 702.
The pressure on-off valve 70 can be used to replace the pressure on-off valves 60 of the first and second embodiments of the present invention, the difference of the pressure on-off valve 70 from the pressure on-off valves 60 is that as the pressure of the bucket 30 is over a predetermined pressure, e.g., the water pressures of the low-pressure cold water intake 713 and the low-pressure cold water port 74 are more than the elasticity of inner parts (not shown) of the resilient element 73 and the first check valve 702, the valve core 72 of the pressure valve 701 is pushed by the water flow to move forward so as to close the high-pressure cold water passage 715 and open the first check valve 702 as illustrated in
As illustrated in
Likewise, the water pump 80 can be used to replace the pressure on-off valve 70 of the second embodiment of the present invention.
While we have shown and described various embodiments in accordance with the present invention, it is clear to those skilled in the art that further embodiments may be made without departing from the scope of the present invention.
Number | Date | Country | Kind |
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097144803 | Nov 2008 | TW | national |