CN215216427U

CN215216427U - Integrated heating system

Info

Publication number: CN215216427U
Application number: CN202021487380.3U
Authority: CN
Inventors: 董布和; 陈毅; 包佈日额
Original assignee: Ordos Qingke Bauhinia Technology Development Co ltd
Current assignee: Ordos Qingke Bauhinia Technology Development Co ltd
Priority date: 2020-07-24
Filing date: 2020-07-24
Publication date: 2021-12-17
Anticipated expiration: 2030-07-24

Abstract

The integrated heat supply system comprises a solar heat exchange device, a heating radiator, a water accumulator and a remote control device, wherein the upper end of the solar heat exchange device is lower than the heating radiator and the water accumulator; a water heat exchanger and an electric heat exchanger are arranged in the water accumulator, and the electric heat exchanger is connected with commercial power; the water outlet end of the solar heat exchange device is sequentially connected with the graphene electric heat exchanger and the circulating pump, the water inlet end of the water heat exchanger and the water inlet end of the heating radiator are both connected with the water outlet end of the circulating pump, and the water return end of the water heat exchanger and the water return end of the heating radiator are both connected with the water return end of the solar heat exchange device; the water inlet end and the water return end of the water heat exchanger and the water inlet end and the water return end of the heating radiator are respectively provided with a valve, and the remote control device is connected with each valve and the temperature detector. This application realizes the natural convection current of water through the position difference to the device, reaches energy-conserving requirement, and solar energy collection pipe or thermal-arrest board are full of water constantly simultaneously and prevent that lack of water adds cold water suddenly and explodes.

Description

Integrated heating system

Technical Field

The utility model relates to a heat supply field especially relates to an integrated heating system.

Background

Solar thermal storage technology and equipment is a ubiquitous technology. The equipment is roughly placed on the roof, so that the maintenance is difficult; solar heating is rarely applied in the north, intermittent heating and easy explosion pipes are adopted, and the energy is idle when the solar heating is applied in winter, so that the use cost is high.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention has been made in order to provide an integrated heating system that overcomes or at least partially solves the above mentioned problems.

According to one aspect of the utility model, an integrated heating system is provided, which comprises a solar heat exchange device, a heating radiator, a water storage device and a remote control device, wherein the upper end position of the solar heat exchange device is lower than the heating radiator and the water storage device; a water heat exchanger and an electric heat exchanger are arranged in the water accumulator, and the electric heat exchanger is connected with commercial power; the water outlet end of the solar heat exchange device is sequentially connected with the graphene electric heat exchanger and the circulating pump, the water inlet end of the water heat exchanger and the water inlet end of the heating radiator are both connected with the water outlet end of the circulating pump, and the water return end of the water heat exchanger and the water return end of the heating radiator are both connected with the water return end of the solar heat exchange device; a hot water temperature detector and a return water temperature detector are respectively arranged at the water outlet end and the return water end of the solar heat exchange device; the water inlet end and the water return end of the water heat exchanger are respectively provided with a fourth valve and a third valve, the water inlet end and the water return end of the heating radiator are respectively provided with a fifth valve and a sixth valve, and the remote control device is connected with each valve and the temperature detector and controls the opening and closing of each valve.

In a possible embodiment, the interior of the water reservoir is further provided with a third water temperature detector.

In a possible implementation mode, the solar heat exchange device comprises an inclined heat collection frame facing the sunlight, a plurality of solar heat collection tubes are fixedly connected above the inclined heat collection frame, the solar heat collection tubes are all connected with a heat collection header box, the upper end of the heat collection header box is connected with a hot water temperature detector, and the lower end of the heat collection header box is connected with a return water temperature detector.

In one possible embodiment, the graphene electric heat exchanger and the remote control device are located below the inclined heat collection frame, the water inlet end of the graphene electric heat exchanger is connected with the upper end of the heat collection header box, and the water return end of the heating radiator is connected with the lower end of the heat collection header box.

In a possible embodiment, the inner cavity of the water reservoir is connected with the outside through two pipelines, one is a hot water outlet and is provided with a first valve, and the other is a tap water inlet and is provided with a second valve.

In one possible embodiment, the graphene electric heat exchanger is model number JZHR24 KW.

In one possible embodiment, the graphene electric heat exchanger is model number JZHR15 KW.

The utility model has the advantages that:

(1) the natural convection of water is realized through the position difference of the device, and the energy-saving requirement is met.

(2) Meanwhile, the solar heat collecting pipe or the heat collecting plate is filled with water at any time to prevent the sudden cold water burst caused by water shortage.

(3) The remote control device enables energy to be reasonably used and distributed, and further saves energy. Meanwhile, the use seasons of heating and heat storage (heating in winter and supplying hot water in spring, summer and autumn) are reasonably distributed.

(4) The solar heat collection and the electric heat exchanger are combined.

Therefore, the problems of intermittent heating, pipe explosion, unreasonable energy distribution, high use cost and the like are solved.

The above description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented according to the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more obvious and understandable, the following detailed description of the present invention is given.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an integrated heating system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a solar heat exchange device according to an embodiment of the present invention;

description of reference numerals:

11-solar heat exchange device, 111-heat collection header box, 112-solar heat collection pipe 113-inclined heat collection frame, 12-graphene electric heat exchanger, 13-remote control device, 14-heating radiator, 15-circulating pump, 16-electric heat exchanger 17-water heat exchanger, 18-water accumulator, 61-hot water temperature detector, 62-return water temperature detector, 63-third water temperature detector, 71-first valve, 72-second valve, 73-third valve, 74-fourth valve, 75-fifth valve, 76-sixth valve.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The terms "comprises" and "comprising," and any variations thereof, in the described embodiments of the invention, and in the claims and drawings, are intended to cover a non-exclusive inclusion, such as a list of steps or elements.

The technical solution of the present invention will be described in further detail with reference to the accompanying drawings and embodiments.

As shown in fig. 1-2, an embodiment of the present invention provides an integrated heating system, including:

the solar heat exchanger 11, the heating radiator 14, the water storage device 18 and the remote control device 13, the upper end position of the solar heat exchanger 11 is lower than the heating radiator 14 and the water storage device 18, so that natural convection of cold water and hot water is formed, and the energy-saving requirement is met by reducing or not using a circulating pump.

The water storage device 18 is internally provided with a water heat exchanger 17 and an electric heat exchanger 16, and the electric heat exchanger 16 is connected with commercial power.

The water outlet end of the solar heat exchange device 11 is sequentially connected with the graphene electric heat exchanger 12 and the circulating pump 15, the water inlet end of the water heat exchanger 17 and the water inlet end of the heating radiator 14 are both connected with the water outlet end of the circulating pump 15, and the water return end of the water heat exchanger 17 and the water return end of the heating radiator 14 are both connected with the water return end of the solar heat exchange device 11.

And a hot water temperature detector 61 and a return water temperature detector 62 are respectively arranged at the water outlet end and the return water end of the solar heat exchange device 11.

The water inlet end and the water return end of the water heat exchanger 17 are respectively provided with a fourth valve 74 and a third valve 73, and the water inlet end and the water return end of the heating radiator 14 are respectively provided with a fifth valve 75 and a sixth valve 76. The remote control device 13 is connected with each valve and the temperature detector, and controls the opening and closing of each valve.

In one example, a third water temperature detector 63 is also provided inside the water reservoir 18.

In one example, the solar heat exchange device 11 includes an inclined heat collecting frame 113 facing the sunlight, a plurality of solar heat collecting pipes 112 are fixedly connected above the inclined heat collecting frame 113, the plurality of solar heat collecting pipes 112 are all connected with a heat collecting header box 111, the upper end of the heat collecting header box 111 is connected with the hot water temperature detector 61, the lower end of the heat collecting header box 111 is connected with the return water temperature detector 62, and since the upper end of the solar heat exchange device 11 is lower than the heating radiator 14 and the water reservoir 18, the aforementioned natural convection for forming cold and hot water is eliminated, the energy saving requirement for the circulating pump is reduced or not applicable, and the solar heat collecting pipes or the heat collecting plates can be filled with water all the time to prevent the cold water from being suddenly added with cold water and burst.

In one example, the graphene electric heat exchanger 12 and the remote control device 13 are located below the inclined heat collection frame 113, a water inlet end of the graphene electric heat exchanger 12 is connected to the upper end of the heat collection header box 111, and a water return end of the heating radiator 14 is connected to the lower end of the heat collection header box 111.

The electric heat exchanger 16 is used for heating water in the water storage device 18 in an electric heat conversion mode, the water heat exchanger 17 is connected with the solar heat exchange device 11 through a pipeline, hot water in the solar heat exchange device 11 can be used for heating water in the water storage device 18 through the water heat exchanger 17, and the water in the water storage device 18 can be used as daily life water. The water heat exchanger 17 and the electric heat exchanger 16 exist at the same time, and the heating is complementary.

The remote control device 13 is connected with the hot water temperature detector 61, the return water temperature detector 62, the third water temperature detector 63, the first valve 71, the second valve 72, the third valve 73, the fourth valve 74, the fifth valve 75, the sixth valve 76 and the power supply, so that automatic control is realized, in winter, hot water in the solar heat exchange device 11 can flow into the heating radiator 14 through the graphene electric heat exchanger 12 for heating, and if the hot water temperature detector 61 detects that the temperature of the hot water in the solar heat exchange device 11 is insufficient, the graphene electric heat exchanger 12 can be controlled by the remote control device 13 to heat the flowing water to the temperature meeting the heating requirement.

In one example, the inner cavity of the reservoir 18 is connected to the outside by two pipes, one is a hot water outlet, provided with a first valve 71, and the other is a tap water inlet, provided with a second valve 72.

In one example, the graphene electrical heat exchanger 12 is model number JZHR24 KW.

In one example, the graphene electrical heat exchanger 12 is model number JZHR15 KW.

Has the advantages that: the utility model discloses an integrated heating system has following beneficial effect:

1. the natural convection of water is realized through the position difference of the device, and the energy-saving requirement is met;

2. meanwhile, the solar heat collecting pipe or the heat collecting plate is filled with water at any time to prevent the sudden cold water burst caused by water shortage.

3. The remote control device enables energy to be reasonably used and distributed, and further saves energy. Meanwhile, the use seasons of heating and heat storage (heating in winter and supplying hot water in spring, summer and autumn) are reasonably distributed.

4. The solar heat collection is combined with the electric heat exchanger, so that the problem of intermittent heating can be solved.

The above-mentioned embodiments further explain the objects, technical solutions and advantages of the present invention in detail, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the protection scope of the present invention, and any modifications, improvements, etc. made on the basis of the technical solutions of the present invention should be included in the protection scope of the present invention.

Claims

1. An integrated heating system is characterized by comprising a solar heat exchange device (11), a heating radiator (14), a water accumulator (18) and a remote control device (13), wherein the upper end of the solar heat exchange device (11) is lower than the heating radiator (14) and the water accumulator (18);

a water heat exchanger (17) and an electric heat exchanger (16) are arranged in the water accumulator (18), and the electric heat exchanger (16) is connected with a mains supply;

the water outlet end of the solar heat exchange device (11) is sequentially connected with the graphene electric heat exchanger (12) and the circulating pump (15), the water inlet end of the water heat exchanger (17) and the water inlet end of the heating radiator (14) are both connected with the water outlet end of the circulating pump (15), and the water return end of the water heat exchanger (17) and the water return end of the heating radiator (14) are both connected with the water return end of the solar heat exchange device (11);

a hot water temperature detector (61) and a return water temperature detector (62) are respectively arranged at the water outlet end and the return water end of the solar heat exchange device (11);

the water inlet end and the water return end of the water heat exchanger (17) are respectively provided with a fourth valve (74) and a third valve (73), the water inlet end and the water return end of the heating radiator (14) are respectively provided with a fifth valve (75) and a sixth valve (76), and the remote control device (13) is connected with each valve and the temperature detector and controls the opening and closing of each valve.

2. Integrated heating system according to claim 1, characterised in that the interior of the water reservoir (18) is further provided with a third water temperature detector (63).

3. The integrated heating system according to claim 1, wherein the solar heat exchanging device (11) comprises an inclined heat collecting frame (113) facing the sunlight, a plurality of solar heat collecting pipes (112) are fixedly connected above the inclined heat collecting frame (113), the plurality of solar heat collecting pipes (112) are all connected with a heat collecting header box (111), the upper end of the heat collecting header box (111) is connected with the hot water temperature detector (61), and the lower end of the heat collecting header box (111) is connected with the return water temperature detector (62).

4. The integrated heating system according to claim 3, wherein the graphene electric heat exchanger (12) and the remote control device (13) are located below the inclined heat collecting frame (113), the water inlet end of the graphene electric heat exchanger (12) is connected with the upper end of the heat collecting header box (111), and the water return end of the heating radiator (14) is connected with the lower end of the heat collecting header box (111).

5. Integrated heating system according to claim 1, characterised in that the inner chamber of the reservoir (18) is connected to the outside by two pipes, one being a hot water outlet, provided with a first valve (71), the other being a tap water inlet, provided with a second valve (72).

6. Integrated heating system according to claim 1, wherein the graphene electric heat exchanger (12) is of the type JZHR24 KW.

7. Integrated heating system according to claim 1, wherein the graphene electric heat exchanger (12) is of the type JZHR15 KW.