CN113758006A - All-purpose water tank - Google Patents

Abstract

The invention provides an all-round water tank which comprises a tank body, a heat exchange water tank and a coupling water tank, wherein the tank body is provided with a water inlet and a water outlet; the heat exchange water tank and the coupling water tank are integrally arranged in the box body; the heat exchange water tank is internally provided with a heat exchange coil which is connected with a heat source and used for heating low-temperature water in the heat exchange water tank by a high-temperature medium of the heat source; the coupling water tank is connected with a heat source and a temperature adjusting tail end. The all-round water tank integrates the heat exchange water tank and the coupling water tank together, so that the occupied space can be reduced; hot water is generated through the heat exchange water tank, so that constant temperature, energy conservation and large water quantity are realized; the coupling of the fluid medium between the heat source and the temperature adjusting tail end is carried out through the coupling water tank, the temperature difference of the supplied and returned medium is reduced, the medium flow is increased, and the energy-saving and stable operation of the system is realized.

Description

All-purpose water tank

Technical Field

The invention belongs to the technical field of heating and ventilation equipment, and particularly relates to an all-round water tank of a single-heat-source or multi-heat-source mixed temperature adjusting facility and a hot water facility.

Background

At present, heating, refrigerating, hot water and other equipment are low in integration degree, occupy space, are high in energy consumption, high in investment cost and high in maintenance cost, and are not beneficial to healthy and stable development of the industry.

The existing temperature adjusting facilities and hot water facilities have the following problems: the temperature difference of the supply medium and the return medium of the temperature regulating system is large, and the energy consumption of the system is high; cold water enters heat source equipment, and the equipment is scaled; the hot water yield is small and the water temperature fluctuation is large.

Disclosure of Invention

Aiming at the problems of low integration degree, high energy consumption and high input cost in the prior art, the invention provides a full-energy water tank, wherein a heat exchange water tank and a coupling water tank are integrated into a whole, so that the space occupation is reduced, and high-temperature water is generated through the heat exchange water tank to realize constant temperature, energy conservation and large water volume; the coupling of the fluid medium between the heat source and the temperature adjusting tail end is carried out through the coupling water tank, the temperature difference of the supplied and returned medium is reduced, the medium flow is increased, and the energy-saving and stable operation of the system is realized through the following technical scheme:

an all-round water tank comprises a tank body, a heat exchange water tank and a coupling water tank;

the heat exchange water tank and the coupling water tank are integrated in a box body;

the heat exchange water tank is internally provided with a heat exchange coil which is connected with a heat source, a high-temperature medium of the heat source can flow into the heat exchange coil and can circulate between the heat source and the heat exchange coil, the heat exchange coil heats low-temperature water in the heat exchange water tank by the high-temperature medium of the heat source, and the water in the heat exchange water tank can provide high-temperature water to the outside after being heated; specifically, the heat source may be: one or more of a wall-hanging furnace, a heat pump, solar energy and waste heat;

the coupling water tank is respectively connected with a heat source and a temperature adjusting tail end, fluid media of the heat source and the temperature adjusting tail end can flow into the coupling water tank, and the fluid media can circulate between the heat source and the coupling water tank and between the temperature adjusting tail end and the coupling water tank; the fluid medium of the heat source can flow into the coupling water tank, the fluid medium in the coupling water tank can flow into the temperature adjusting tail end, the coupling water tank is used as a connecting bridge of the fluid medium between the heat source and the temperature adjusting tail end, and the fluid medium among the heat source, the temperature adjusting tail end and the coupling water tank can form circulating flow, so that the energy consumption is reduced; specifically, the heat source connected with the coupling water tank and the heat source connected with the heat exchange coil are the same heat source or different heat sources, and can be one or more of wall-mounted furnaces, heat pumps, solar energy and other heat sources; the tempering tip may be: one or more of a fan coil, a floor heating coil, a radiator and a plate heat exchanger.

Further limiting, a heat insulation material layer is arranged among the heat exchange water tank, the coupling water tank and the tank body; specifically, the heat insulation material layer can be made of polyurethane foam material.

Further limiting, a high-temperature water outlet pipe is arranged on the side wall of the top of the heat exchange water tank, a valve and a hot water circulating pump are mounted on the high-temperature water outlet pipe, and specifically, the valve is arranged between the hot water circulating pump and the heat exchange water tank; the bottom lateral wall of heat exchange water tank is equipped with the inlet tube, installs the valve on the inlet tube, and the external water source of inlet tube, during operation low temperature water gets into heat exchange water tank.

Further limiting, a buffer baffle is arranged in the heat exchange water tank, the buffer baffle divides the heat exchange water tank into an upper cavity and a lower cavity, the heat exchange coil is positioned in the upper cavity, a distributed water injection pipe is arranged in the lower cavity, and the distributed water injection pipe is connected with a water inlet pipe; the distributed water injection pipe and the buffer clapboard are used for reducing the impact of low-temperature water in the lower chamber on high-temperature water in the upper chamber and promoting the constant water temperature in the upper chamber; specifically, a plurality of water injection nozzles are arranged on the distributed water injection pipe, so that low-temperature water is uniformly injected into the lower cavity; specifically, when low-temperature water is continuously injected into the lower chamber, the low-temperature water in the lower chamber passes through the plurality of through holes on the buffer partition plate and is in a cylindrical shape to support the high-temperature water in the upper chamber upwards, so that the stirring of the high-temperature water in the upper chamber by the low-temperature water entering the upper chamber is reduced, the fluctuation of the temperature of the high-temperature water in the upper chamber is reduced, and the temperature constancy of the high-temperature outlet water is promoted.

Further limiting, a controller is arranged in the box body, a water flow sensor is arranged on the high-temperature water outlet pipe, and specifically, the water flow sensor is arranged between the valve and the hot water circulating pump; the hot water circulating pump and the water flow sensor are electrically connected with the controller, and the water flow sensor is used for detecting a water flow signal and transmitting the water flow signal to the controller; specifically, the controller is a programmable integrated touch numerical control PLC, which is a prior art device.

The water inlet pipe is further limited, a circulating water return pipe is arranged on the water inlet pipe in a bypass mode, the circulating water return pipe is externally connected with circulating water, an electric valve and a one-way valve are installed on the circulating water return pipe, specifically, the one-way valve is arranged between the electric valve and the water inlet pipe, the joint of the circulating water return pipe and the water inlet pipe is arranged between a valve on the water inlet pipe and the heat exchange water tank, and the circulating water return pipe is not controlled by the valve on the water inlet pipe; the circulating backwater is connected with the heat circulating pipe, and the low-temperature water in the heat circulating pipe can return to the heat exchange water tank.

Further limited, a magnesium rod is arranged in the heat exchange water tank, and the magnesium rod can reduce scaling.

Further inject, the last installation of heat exchange water tank is equipped with the temperature gauge, and the temperature gauge can monitor the temperature and the pressure in the heat exchange water tank.

Further limiting, a safety valve is arranged on the heat exchange water tank; when the temperature in the heat exchange water tank exceeds the limit value, the safety valve is opened, high-temperature hot water is discharged outside, and low-temperature water enters the heat exchange water tank to achieve the purpose of cooling; when the pressure exceeds the limit value, the safety valve is opened to release the pressure of the heat exchange water tank; specifically, the technical structure of the safety valve is known in the art, and will not be described in detail herein.

Further limiting, a temperature measurement blind pipe is arranged on the heat exchange water tank and used for installing a temperature sensor of a heat source, and the heat source is convenient to monitor and measure the temperature.

It is further defined that the coupling water tank is provided with a heat source circulation pipe, and a fluid medium circulates between the heat source and the coupling water tank when in operation.

Further limiting, the coupling water tank is provided with a temperature-adjusting water inlet pipe and a temperature-adjusting water outlet pipe which are connected with the temperature-adjusting tail end, and a fluid medium circulates between the temperature-adjusting tail end and the coupling water tank during working; the temperature adjusting water outlet pipe is provided with a valve and a system circulating pump, specifically, the valve is arranged between the system circulating pump and the coupling water tank, and the system circulating pump is electrically connected with the controller; and a valve and a filtering device are arranged on the temperature adjusting water inlet pipe.

And a bypass pipe is arranged between the temperature-adjusting water outlet pipe and the temperature-adjusting water inlet pipe, and a differential pressure bypass valve is arranged on the bypass pipe and used for protecting a system circulating pump.

Further limit, the filter that the temperature adjusting water inlet pipe was installed is used for filtration system impurity.

Further limiting, an automatic exhaust valve is arranged on the coupling water tank and used for automatically exhausting the system, and efficient operation of the system is guaranteed.

Further limiting, a temperature probe is arranged on the coupling water tank and used for monitoring the temperature of the water in the system in the coupling water tank, and specifically, the temperature probe is electrically connected with the controller.

Further inject, the bottom of heat exchange water tank and coupling water tank all is equipped with the blow off pipe, and the installation is equipped with the blowoff valve on the blow off pipe, and the external sewer of blow off pipe can carry out the blowdown of system through the blow off pipe.

According to the technical scheme, the all-round water tank provided by the invention has the beneficial effects that: the all-round water tank heat exchange water tank and the coupling water tank are integrated together, so that the space occupation can be reduced, and high-temperature water is generated through the heat exchange water tank, so that constant temperature, energy conservation and large water volume are realized; the coupling of the fluid medium between the heat source and the temperature adjusting tail end is carried out through the coupling water tank, the temperature difference of the supplied and returned medium is reduced, the medium flow is increased, and the energy-saving and stable operation of the system is realized

Drawings

In order to more clearly illustrate the detailed description of the invention or the technical solutions in the prior art, the drawings that are needed in the detailed description of the invention or the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

FIG. 1 is a schematic structural diagram of the present invention.

In the drawings: 1-a box body, 2-a heat exchange water tank, 3-a coupling water tank, 4-a heat exchange coil pipe, 5-a heat insulation material layer, 6-a high-temperature water outlet pipe, 7-a valve, 8-a hot water circulating pump, 9-a water inlet pipe, 10-a buffer clapboard, 11-a distributed water injection pipe, 12-a controller, 13-a water flow sensor, 14-a circulating water return pipe, 15-an electric valve, 16-a one-way valve, 17-a magnesium rod, 18-a temperature pressure gauge, 19-a safety valve, 20-a temperature measuring blind pipe, 21 and 22-a heat source circulating pipe, 23-a temperature adjusting water outlet pipe, 24-a temperature adjusting water inlet pipe, 25-a system circulating pump, 26-a bypass pipe, 27-a differential pressure bypass valve, 28-a filter, 29-an automatic air inlet valve and 30-a temperature probe, 31-a sewage discharge pipe and 32-a sewage discharge valve.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

In the description of the present application, it is to be understood that the terms "upper", "lower", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

As shown in fig. 1, an all-purpose water tank includes a tank body 1, a heat exchange water tank 2 and a coupling water tank 3;

the heat exchange water tank 2 and the coupling water tank 3 are integrally arranged in the tank body 1;

the heat exchange water tank 2 is internally provided with a heat exchange coil 4, the heat exchange coil 4 is connected with a heat source, a high-temperature medium of the heat source flows into the heat exchange coil 4 and circulates between the heat source and the heat exchange coil 4 when the heat exchange water tank works, the heat exchange coil 4 is used for carrying out heat exchange between the high-temperature medium of the heat source and low-temperature water in the heat exchange water tank 2 so as to heat the low-temperature water in the heat exchange water tank 2, and the low-temperature water in the heat exchange water tank 2 can be heated to provide high-temperature water outwards; specifically, the heat source can be a wall-hanging stove, a heat pump, solar energy, waste heat and other heat sources;

a high-temperature water outlet pipe 6 is arranged on the side wall of the top of the heat exchange water tank 2, a valve 7 and a hot water circulating pump 8 are arranged on the high-temperature water outlet pipe 6, and specifically, the valve 7 is arranged between the hot water circulating pump 8 and the heat exchange water tank 2; a water inlet pipe 9 is arranged on the side wall of the bottom of the heat exchange water tank 2, a valve 7 is arranged on the water inlet pipe 9, the water inlet pipe 9 is externally connected with a water source, and low-temperature water enters the heat exchange water tank 2 during operation;

a buffer baffle plate 10 is arranged in the heat exchange water tank 2, the heat exchange water tank 2 is divided into an upper cavity and a lower cavity by the buffer baffle plate 10, the heat exchange coil 4 is positioned in the upper cavity, a distributed water injection pipe 11 is arranged in the lower cavity, and the distributed water injection pipe 11 is connected with a water inlet pipe 9; the distributed water injection pipe 11 and the buffer partition plate 10 are used for reducing the impact of low-temperature water in the lower chamber on high-temperature water in the upper chamber and promoting the constant water temperature in the upper chamber; specifically, a plurality of water injection nozzles are arranged on the distributed water injection pipe 11, so that low-temperature water is uniformly injected into the lower cavity; specifically, when low-temperature water is continuously injected into the lower chamber, the low-temperature water in the lower chamber passes through the plurality of through holes on the buffer partition plate 10 and is in a cylindrical shape to support the high-temperature water in the upper chamber upwards, so that the stirring of the high-temperature water in the upper chamber by the low-temperature water entering the upper chamber is reduced, the fluctuation of the high-temperature water in the upper chamber is reduced, and the constancy of the high-temperature water is promoted;

a controller 12 is arranged in the box body 1, a water flow sensor 13 is arranged on the high-temperature water outlet pipe 6, and specifically, the water flow sensor 13 is arranged between the valve 7 and the hot water circulating pump 8; the hot water circulating pump 8 and the water flow sensor 13 are both electrically connected with the controller 12, and the water flow sensor 13 is used for detecting a water flow signal and transmitting the water flow signal to the controller 12; specifically, the controller 12 is a programmable integrated touch numerical control PLC, which is a prior art device;

the coupling water tank 3 is externally connected with a heat source and a temperature adjusting tail end respectively when working, fluid media of the heat source and the temperature adjusting tail end can flow into the coupling water tank 3, and the fluid media can circulate between the heat source and the coupling water tank 3 and between the temperature adjusting tail end and the coupling water tank 3; the fluid medium of the heat source can flow into the coupling water tank 3, the fluid medium in the coupling water tank 3 can flow into the temperature adjusting tail end, the coupling water tank 3 is used as a connecting bridge of the fluid medium between the heat source and the temperature adjusting tail end, and the fluid medium among the heat source, the temperature adjusting tail end and the coupling water tank can form circulating flow, so that the energy consumption is reduced; specifically, the heat source connected to the coupling water tank 3 and the heat source connected to the heat exchange coil 4 are the same heat source or different heat sources, and may be one or more of a wall-hanging furnace, a heat pump, solar energy, waste heat and other heat sources; the temperature adjusting terminal can be one or more of a fan coil, a floor heating coil, a radiator and a plate heat exchanger;

specifically, the side wall of the coupling water tank is provided with heat source circulating pipes 21 and 22, and fluid medium circulates between the heat source and the coupling water tank when the coupling water tank works;

the side wall of the coupling water tank 3 is provided with a temperature adjusting water outlet pipe 23 and a temperature adjusting water inlet pipe 24 which are connected with the temperature adjusting tail end, and a fluid medium circulates between the coupling water tank 3 and the temperature adjusting equipment when the coupling water tank works; the temperature adjusting water outlet pipe 23 is provided with a valve 7 and a system circulating pump 25, specifically, the valve 7 is arranged between the system circulating pump 25 and the coupling water tank 3, and specifically, the system circulating pump 25 is electrically connected with the controller 12; and a valve 7 is arranged on the temperature-adjusting water inlet pipe 24.

In the embodiment, a heat insulation material layer 5 is arranged between the heat exchange water tank 2, the coupling water tank 3 and the box body 1; specifically, the thermal insulation material layer 5 may be made of a polyurethane foam material.

In this embodiment, a circulating water return pipe 14 is provided on the water inlet pipe 9 by-pass, the circulating water return pipe 14 is externally connected with the heat circulating water, an electric valve 15 and a one-way valve 16 are installed on the circulating water return pipe 14, specifically, the one-way valve 16 is located between the electric valve 15 and the water inlet pipe 9, the connection between the circulating water return pipe 14 and the water inlet pipe 9 is located between the valve 7 on the water inlet pipe 9 and the heat exchange water tank 2, and the circulating water return pipe 14 is not controlled by the valve 7 on the water inlet pipe 9; the circulating water return pipe 14 is connected with a heat circulating pipe to realize zero cold water and hot water pressurization, and the electric valve 15 is electrically connected with the controller 12.

In this embodiment, the magnesium rod 17 is installed in the heat exchange water tank 2, and the magnesium rod 17 can reduce scaling.

In this embodiment, the heat exchange water tank 2 is provided with a temperature gauge 18, and the temperature gauge 18 can monitor the temperature and pressure in the heat exchange water tank 2.

In this embodiment, a safety valve 19 is installed on the heat exchange water tank 2; when the temperature in the heat exchange water tank 2 exceeds the limit value, the safety valve 19 is opened, high-temperature water is discharged outside, and low-temperature water enters the heat exchange water tank 2 to achieve the purpose of cooling; when the pressure exceeds the limit value, the safety valve 19 is opened to release the pressure of the heat exchange water tank 2; specifically, the technical structure of the relief valve 19 is well known and will not be described herein.

In this embodiment, the heat exchange water tank 2 is provided with a temperature measurement blind pipe 20, and the temperature measurement blind pipe 20 is used for installing a temperature sensor of a heat source, so as to facilitate monitoring and temperature measurement of the heat source.

In this embodiment, a bypass pipe 26 is installed between the temperature adjusting water outlet pipe 23 and the temperature adjusting water inlet pipe 24, a differential pressure bypass valve 27 is installed on the bypass pipe 26, and the differential pressure bypass valve 27 is used for protecting a system circulation pump 25.

In this embodiment, the temperature-adjusting water inlet pipe 24 is provided with a filter 28, and the filter 28 is used for filtering system impurities.

In this embodiment, an automatic exhaust valve 29 is arranged on the coupling water tank 3, and the automatic exhaust valve 29 is used for automatic exhaust of the system, so that efficient operation of the system is ensured.

In this embodiment, the coupling water tank 3 is provided with a temperature probe 30, the temperature probe 30 is used for monitoring the temperature of a system medium in the coupling water tank 3, and specifically, the temperature probe 30 is electrically connected to the controller 12.

In this embodiment, the bottom of heat exchange water tank 2 and coupling water tank 3 all is equipped with blow off pipe 31, and the installation is equipped with blowoff valve 32 on blow off pipe 31, and the external sewer of blow off pipe 31 can carry out the blowdown of system through blow off pipe 31.

The all-round water tank heat exchange water tank 2 and the coupling water tank 3 are integrated together, so that the space occupation can be reduced, and high-temperature water is generated through the heat exchange water tank 2, so that constant temperature, energy conservation and large water volume are realized; the coupling of the fluid medium between the heat source equipment and the temperature adjusting tail end is carried out through the coupling water tank 3, the temperature difference of the supplied and returned medium is reduced, the medium flow is increased, and the energy-saving and stable operation of the system is realized; by arranging the magnesium rod 17, the scale formation of the equipment can be reduced; this all-round water tank passes through intellectual detection system temperature pressure, rivers, realizes intelligent control, avoids equipment to open frequently to stop.

Claims (2)

1. An all-round water tank which is characterized in that: comprises a box body, a heat exchange water tank and a coupling water tank;

the heat exchange water tank and the coupling water tank are integrally arranged in the box body;

the heat exchange water tank is internally provided with a heat exchange coil, and the heat exchange coil heats low-temperature water by using a high-temperature medium of a heat source to generate high-temperature water;

the coupling water tank is connected with a heat source and a temperature adjusting tail end, so that the temperature difference of the supplied and returned media is reduced, and the flow of the media is increased.

2. The universal water tank as claimed in claim 1, wherein: the heat exchange water tank is internally provided with a buffer baffle plate, the buffer baffle plate divides the heat exchange water tank into an upper cavity and a lower cavity, the heat exchange coil is positioned in the upper cavity, the lower cavity is internally provided with a distributed water injection pipe, and the distributed water injection pipe is connected with a water inlet pipe; a plurality of through holes are uniformly distributed on the buffer baffle plate, and the upper cavity and the lower cavity are communicated through the through holes.

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