CN113847642A

CN113847642A - Heating equipment capable of refrigerating

Info

Publication number: CN113847642A
Application number: CN202111080126.0A
Authority: CN
Inventors: 王静杭
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-09-15
Filing date: 2021-09-15
Publication date: 2021-12-28
Anticipated expiration: 2041-09-15
Also published as: CN113847642B

Abstract

The invention discloses heating equipment capable of refrigerating, which comprises a radiator, a cold source and a heat source; the water outlet end of the cold source, the water outlet end of the heat source and the water inlet end of the radiator are communicated through a first three-way reversing valve, and the water inlet end of the cold source, the water inlet end of the heat source and the water outlet end of the radiator are communicated through another first three-way reversing valve; the water outlet end of the radiator is communicated with the corresponding first three-way reversing valve, and the water inlet end of the radiator is communicated with the corresponding first three-way reversing valve through heat-insulating pipelines. The invention adds a refrigeration function on the basis of the existing heating, has dual purposes of cooling and heating, and is beneficial to blocking the way of virus air transmission.

Description

Heating equipment capable of refrigerating

Technical Field

The invention relates to the field of heating, in particular to heating equipment capable of refrigerating.

Background

The existing air conditioner generally has the functions of refrigeration and heating, and meets the requirements of being warm in winter and cool in summer. However, with the development of epidemic situation, the transmission capability of the virus is stronger and stronger, the air can be infected, and the ventilation function of the air conditioner creates certain conditions for the transmission of the virus.

In order to avoid the above problems, the conventional heater becomes a safe heating system, and the heater is a necessary device in the north. The heat source is typically hot water or steam which is piped to the radiators in the room and circulated. However, the heater only has a heating function, does not have a refrigerating function, and cannot be applied in summer, particularly in the south, so that the heater is rare in the south, difficult to popularize and not beneficial to inhibiting virus air transmission.

In addition, because the heating adopts water as the medium of heat transfer, the incrustation scale is constantly accumulated in the radiator, and the incrustation scale can produce certain resistance to the flow of hot water, and then influences the heating effect. The existing heating plate has no function of removing water scale, the heating effect is obviously weakened after the heating plate is used for a period of time, the utilization rate of heat is reduced, and the phenomenon of energy waste is serious.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides heating equipment capable of refrigerating, which comprises a radiator, a cold source and a heat source; the water outlet end of the cold source, the water outlet end of the heat source and the water inlet end of the radiator are communicated through a first three-way reversing valve, and the water inlet end of the cold source, the water inlet end of the heat source and the water outlet end of the radiator are communicated through another first three-way reversing valve; the water outlet end of the radiator is communicated with the corresponding first three-way reversing valve, and the water inlet end of the radiator is communicated with the corresponding first three-way reversing valve through heat-insulating pipelines.

The invention has the beneficial effects that: the radiator is arranged indoors, and the cold source and the heat source are both arranged outdoors.

1. In winter, the two first three-way reversing valves are switched into a pipeline of a heat source, namely, the radiator is communicated with the heat source to form circulation, and the heat source is indoor continuous heat. The heating mode is the same as that of the existing heating.

2. In summer, the two first three-way reversing valves are switched into a pipeline of a cold source, namely, the radiator is communicated with the cold source to form circulation, so that indoor continuous refrigeration is realized, and the cooling requirement is met.

The refrigerator has two functions of refrigeration and heating, can be used all the year round, breaks regional limitation, and is beneficial to large-area popularization. In addition, air convection cannot be formed between the refrigerating function and the heating function and the outdoor, so that the virus propagation in the air is reduced and inhibited.

Preferably, the cold source comprises a cold water pool; and a water inlet and a water outlet of the cold water tank are respectively communicated with the two first three-way reversing valves.

Preferably, the cold source comprises a refrigeration unit; the refrigeration unit comprises a compressor, an evaporator, a throttle valve and a condenser which are sequentially communicated, wherein the evaporator is positioned in the cold water pool and used for reducing the water temperature in the cold water pool. The heat at the evaporator is transferred to the condenser by the compressor, and the condenser radiates heat through the cooling fan, so that the temperature of water in the cold water pool is reduced, and refrigeration is continuously performed.

Preferably, a control unit is included; the first three-way reversing valves are all electromagnetic valves, and the control unit is electrically connected with the two first three-way reversing valves respectively.

Preferably, the control unit is provided with a cooling button and a warming button. The control unit is arranged indoors, and a user can select refrigeration or heating by himself or herself, so that the use is convenient.

Preferably, the temperature sensor probe is arranged on the radiator, the control unit is provided with a display, and the temperature sensor probe is electrically connected with the control unit and used for displaying the temperature of the radiator. The temperature sensor probe monitors the real-time temperature of the radiator, and the control unit compares the real-time temperature fed back by the temperature sensor probe with the set temperature, so that the opening degree of the first three-way reversing valve at the cold source water inlet end or the opening degree of the first three-way reversing valve at the heat source water inlet end is controlled, and the temperature is adjusted.

Preferably, the heat source is a fuel boiler, an electrically heated boiler or a geothermal system.

Preferably, the heat sink includes a housing, a heat pipe, a first driver, a second driver, and a choke;

the heat conduction pipe is fixed in the shell, the heat conduction pipe is bent in the shell for multiple times, and two ends of the heat conduction pipe extend out of the shell, so that the two extending ends form a water inlet end and a water outlet end of the radiator;

the flow blocking pipes are arranged in a plurality of numbers, each flow blocking pipe is connected to the inside of the heat conduction pipe, and all the flow blocking pipes are distributed in parallel; the side surface of each flow blocking pipe is hinged with a plurality of flow deflectors, and all the flow deflectors of each flow blocking pipe are distributed along the axial direction in a staggered manner; a traction rope capable of sliding along the axial direction is arranged inside each flow blocking pipe, one end of each flow deflector is hinged with the traction rope, an opening matched with each flow deflector is formed in the side surface of each flow blocking pipe, and the flow deflectors are radially unfolded or axially closed in the openings by sliding the traction ropes;

the hauling ropes in all the choke pipes in the middle of the shell are sequentially connected at the head, the tail ends of the hauling ropes of the two choke pipes on the two sides of the shell are respectively connected with the output end of the first driver and the output end of the second driver in the shell, all the hauling ropes are pulled to slide through the first driver and the second driver simultaneously, and then all the flow deflectors are unfolded or closed in the heat conduction pipes.

Preferably, the radiator comprises a water storage tank; the water storage tank is fixed with the shell, one water outlet nozzle of the water storage tank, the water inlet end of the radiator and the corresponding heat preservation pipeline are in through connection through a second three-way reversing valve, and the other water outlet nozzle of the water storage tank, the water outlet end of the radiator and the corresponding heat preservation pipeline are in through connection through the other second three-way reversing valve; and a water pump for pumping descaling liquid in the water storage tank into the heat conduction pipe is arranged in the water storage tank.

Preferably, a guide wheel which can rotate and is positioned in the shell is arranged at the tail end of each choke tube, and each traction rope passes through the corresponding guide wheel to be connected with the adjacent traction line.

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 embodiment;

FIG. 2 is a partial view of FIG. 1;

FIG. 3 is an internal view of the bottom view of FIG. 2;

FIG. 4 is an enlarged view taken at A in FIG. 3;

FIG. 5 is a schematic structural diagram of a choke tube in this embodiment;

fig. 6 is a schematic structural view of the guide vane shown in fig. 5 after being unfolded;

fig. 7 is an enlarged view at B in fig. 6.

In the attached drawings, a radiator 1, a cold source 2, a heat source 3, a first three-way reversing valve 4, a heat preservation pipeline 5, a shell 6, a heat conduction pipe 7, a first driver 8, a second driver 9, a choke pipe 10, a flow deflector 11, a traction rope 12, an opening 13, a protrusion 14, a guide wheel 15, a winch 16, a motor 17, a water storage tank 18, a second three-way reversing valve 19, a heat dissipation strip 20 and a water pump 21.

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.

It is to be noted that, unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the invention pertains.

As shown in fig. 1, the present embodiment provides a heating apparatus capable of cooling, which includes a radiator 1, a cold source 2, and a heat source 3. The water outlet end of the cold source 2 and the water outlet end of the heat source 3 are communicated with the water inlet end of the radiator 1 through a first three-way reversing valve 4, and the water inlet end of the cold source 2 and the water inlet end of the heat source 3 are communicated with the water outlet end of the radiator 1 through another first three-way reversing valve 4; the water outlet end of the radiator 1 is communicated with the corresponding first three-way reversing valve 4, and the water inlet end of the radiator 1 is communicated with the corresponding first three-way reversing valve 4 through a heat insulation pipeline 5. In addition, the outer surface of the radiator 1 is also provided with radiating strips 20, so that the heat exchange efficiency is improved.

Wherein the cold source 2 comprises a cold water pool; and a water inlet and a water outlet of the cold water tank are respectively communicated with the two first three-way reversing valves 4. The cold source 2 comprises a refrigeration unit; the refrigeration unit comprises a compressor, an evaporator, a throttle valve and a condenser which are sequentially communicated, wherein the evaporator is positioned in the cold water pool and used for reducing the water temperature in the cold water pool. The heat at the evaporator is transferred to the condenser by the compressor, and the condenser radiates heat through the cooling fan, so that the temperature of water in the cold water pool is reduced, and refrigeration is continuously performed. And the heat source 3 is a fuel boiler, an electric heating boiler or a geothermal system, and the type of the heat source 3 is selected according to specific situations.

The present embodiment controls the temperature as follows:

as shown in fig. 2 to 7, includes a control unit; the first three-way reversing valves 4 are all electromagnetic valves, and the control unit is electrically connected with the two first three-way reversing valves 4 respectively. The control unit is provided with a refrigeration button and a heating button. The control unit is arranged indoors, and a user can select refrigeration or heating by himself or herself, so that the use is convenient. Still including being located the temperature sensor probe of radiator 1, the control unit is equipped with the display, the temperature sensor probe is connected with the control unit electricity for show the temperature of radiator 1. The temperature sensor probe monitors the real-time temperature of the radiator 1, and the control unit compares the real-time temperature fed back by the temperature sensor probe with the set temperature, so that the opening degree of the first three-way reversing valve 4 at the water inlet end of the cooling source 2 or the opening degree of the first three-way reversing valve 4 at the water inlet end of the heat source 3 is controlled, and the temperature is adjusted.

In order to solve the problem of scale in the heat sink 1, the heat sink 1 in the present embodiment includes a housing 6, a heat pipe 7, a first driver 8, a second driver 9, and a choke pipe 10. The heat pipe 7 is fixed in the housing 6, the heat pipe 7 is bent in the housing 6 many times and two ends of the heat pipe 7 extend out of the housing 6, so that the two extended ends form a water inlet end and a water outlet end of the heat sink 1.

The choke pipe 10 is provided in plurality, each choke pipe 10 is connected to the inside of the heat conductive pipe 7, and all choke pipes 10 are distributed in parallel. Specifically, the parts of the heat conductive pipes 7 are arranged longitudinally in parallel, i.e. a choke 10 is provided in each longitudinal part of the heat conductive pipes 7. The side surface of each choke pipe 10 is hinged with a plurality of guide vanes 11, and all the guide vanes 11 of each choke pipe 10 are distributed along the axial direction in a staggered manner; each choke tube 10 is provided with a hauling rope 12 inside and capable of sliding along the axial direction, one end of the deflector 11 is hinged with the hauling rope 12, the side surface of the choke tube 10 is provided with an opening 13 matched with the deflector 11, and the deflector 11 is radially unfolded or axially closed in the opening 13 by sliding the hauling rope 12. All the openings 13 of each choke tube 10 face the same direction, and the included angles between all the openings 13 and the central axis are acute angles of the same size. In the process that the guide vane 11 is moved by the traction line, the guide vane 11 is supported by the protrusion 14 at the opening 13, so that the guide vane 11 is radially expanded, and the opening 13 limits the maximum opening degree of the expansion.

The pulling ropes 12 in all the choke tubes 10 in the middle of the housing 6 are sequentially connected to one another, and specifically, a guide wheel 15 which is rotatable and is located in the housing 6 is provided near the end of each choke tube 10, and each pulling rope 12 is connected to the adjacent pulling wire by bypassing the corresponding guide wheel 15. The ends of the pulling ropes 12 of the two choke tubes 10 located at both sides of the housing 6 are respectively connected with the output end of the first driver 8 and the output end of the second driver 9 in the housing 6, and all the pulling ropes 12 are pulled to slide by the first driver 8 and the second driver 9 simultaneously, so that all the flow deflectors 11 are unfolded or closed in the heat conducting tubes 7. The first driver 8 and the second driver 9 are both motors 17 with winches 16, the pulling rope 12 is wound on the winches 16, and the motors 17 drive the winches 16 to rotate, so that the pulling rope 12 is recovered or released.

The radiator 1 of the present embodiment further comprises a water storage tank 18, and the water storage tank 18 is filled with a descaling agent. The water storage tank 18 is fixed with the shell 6, one water outlet nozzle of the water storage tank 18, the water inlet end of the radiator 1 and the corresponding heat preservation pipeline 5 are in conduction connection through a second three-way reversing valve 19, and the other water outlet nozzle of the water storage tank 18, the water outlet end of the radiator 1 and the corresponding heat preservation pipeline 5 are in conduction connection through the other second three-way reversing valve 19; a water pump 21 for pumping the descaling liquid in the water storage tank 18 into the heat conduction pipe 7 is arranged in the water storage tank 18.

The descaling principle is as follows: in the descaling mode, the two second three-way reversing valves 19 switch pipelines to enable the water storage tank 18 to be communicated with the radiator 1, and the water pump 21 works to enable the descaling agent to circularly flow in the water storage tank 18 and the radiator 1. The first driver 8 and the second driver 9 pull all the hauling ropes 12 to slide simultaneously, so that all the flow deflectors 11 are unfolded in the heat conduction pipe 7, the unfolded flow deflectors 11 disturb water flow, and a descaling agent is guided to impact scales, impurities and the like attached to the inner surface of the heat conduction pipe 7, so that the descaling effect is improved. In addition, the water pump 21 can rotate forward and backward to change the direction of the control water flow, so that the descaling effect is further improved.

Heating or cooling mode: two second three-way reversing valves 19 switch pipelines to disconnect the water storage tank 18 and the radiator 1, the radiator 1 is communicated with the heat preservation pipeline 5, the first driver 8 and the second driver 9 reversely pull all the traction ropes 12 to slide at the same time, and then all the guide vanes 11 are closed in the corresponding openings 13, so that the resistance to hot water or cold water is reduced, and a normal heating circulation pipeline or a normal refrigerating circulation pipeline is formed.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention, and they should be construed as being included in the following claims and description.

Claims

1. A heating apparatus capable of cooling, characterized in that: comprises a radiator, a cold source and a heat source; the water outlet end of the cold source, the water outlet end of the heat source and the water inlet end of the radiator are communicated through a first three-way reversing valve, and the water inlet end of the cold source, the water inlet end of the heat source and the water outlet end of the radiator are communicated through another first three-way reversing valve; the water outlet end of the radiator is communicated with the corresponding first three-way reversing valve, and the water inlet end of the radiator is communicated with the corresponding first three-way reversing valve through heat-insulating pipelines.

2. A coolable heating installation as claimed in claim 1, characterized in that: the cold source comprises a cold water pool; and a water inlet and a water outlet of the cold water tank are respectively communicated with the two first three-way reversing valves.

3. A coolable heating installation as claimed in claim 1, characterized in that: the cold source comprises a refrigeration unit; the refrigeration unit comprises a compressor, an evaporator, a throttle valve and a condenser which are sequentially communicated, wherein the evaporator is positioned in the cold water pool and used for reducing the water temperature in the cold water pool.

4. A coolable heating installation as claimed in claim 1, characterized in that: comprises a control unit; the first three-way reversing valves are all electromagnetic valves, and the control unit is electrically connected with the two first three-way reversing valves respectively.

5. The heating installation capable of cooling as claimed in claim 4, wherein: the control unit is provided with a refrigeration button and a heating button.

6. The heating installation capable of cooling as claimed in claim 5, wherein: including being located the temperature sensor probe of radiator, the control unit is equipped with the display, the temperature sensor probe is connected with the control unit electricity for show the temperature of radiator.

7. A coolable heating installation as claimed in claim 1, characterized in that: the heat source is a fuel boiler or an electric heating boiler.

8. A coolable heating installation as claimed in claim 1, characterized in that: the radiator comprises a shell, a heat conduction pipe, a first driver, a second driver and a choke pipe;

9. The heating installation capable of cooling as claimed in claim 8, wherein: the radiator comprises a water storage tank; the water storage tank is fixed with the shell, one water outlet nozzle of the water storage tank, the water inlet end of the radiator and the corresponding heat preservation pipeline are in through connection through a second three-way reversing valve, and the other water outlet nozzle of the water storage tank, the water outlet end of the radiator and the corresponding heat preservation pipeline are in through connection through the other second three-way reversing valve; and a water pump for pumping descaling liquid in the water storage tank into the heat conduction pipe is arranged in the water storage tank.

10. The heating installation capable of cooling as claimed in claim 8, wherein: the tail end close to each choke tube is provided with a guide wheel which can rotate and is positioned in the shell, and each traction rope bypasses the corresponding guide wheel to be connected with the adjacent traction line.