CN214470226U - Novel radiator energy recuperation device - Google Patents

Abstract

The utility model discloses a novel radiator energy recovery device, which comprises an installation bottom plate, a heat exchange mechanism and an energy recovery mechanism; installing a bottom plate: the lower surface of the mounting plate is provided with a mounting bracket, four corners of the bottom of the mounting bracket are provided with universal wheels, the right side of the upper surface of the mounting base plate is provided with a mounting square opening, and the left side of the upper surface of the mounting base plate is provided with a radiator; the heat exchange mechanism comprises: the heat exchange mechanism is arranged on the right side of the upper surface of the mounting bottom plate, the lower end opening of the heat exchange mechanism corresponds to the mounting square opening, the upper end water inlet of the heat exchange mechanism is communicated with the upper end water outlet of the radiator through a pipeline, and the lower end water outlet of the heat exchange mechanism is communicated with the lower end water inlet of the radiator through a pipeline; the energy recovery mechanism comprises: set up in the inside left end of installing support, energy recuperation mechanism's upper end and heat transfer mechanism fixed connection, this novel radiator energy recuperation device can realize the recycle of energy, reduces the waste of resource.

Description

Novel radiator energy recuperation device

Technical Field

The utility model relates to a radiator energy recuperation technical field specifically is a novel radiator energy recuperation device.

Background

Radiators are important and essential components of hot water heating systems. The hot water is cooled in the radiator to supply heat to the indoor, thereby achieving the purpose of heating. The metal consumption and the manufacturing cost of the radiator occupy a considerable proportion in the heating system, so that the radiator is correctly selected and used in relation to the economic index and the operation effect of the system, and the radiator is divided into a radiation radiator and a convection radiator according to the heat exchange mode. Convective heat sinks, sometimes referred to as "convectors", have a convective heat sink heat dissipation of almost 100%; compared with a convection radiator, other radiators radiate heat by convection and radiation at the same time, and the radiators are divided into a cast iron radiator, a steel radiator and radiators made of other materials according to the materials. Other material radiators include the radiator of materials such as aluminium, copper, steel aluminium complex, copper aluminium complex, stainless steel aluminium complex and enamel, and traditional radiator lacks energy recuperation device, and the heat energy that the radiator distributed out can not effectively be utilized, can't realize the recycle of energy, causes the waste of resource, consequently in order to solve this type of problem, we propose a novel radiator energy recuperation device.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide a novel radiator energy recuperation device, can realize the recycle of energy, can effectively solve the problem among the background art.

In order to achieve the above object, the utility model provides a following technical scheme: a novel radiator energy recovery device comprises an installation bottom plate, a heat exchange mechanism and an energy recovery mechanism;

installing a bottom plate: the lower surface of the mounting plate is provided with a mounting bracket, four corners of the bottom of the mounting bracket are provided with universal wheels, the right side of the upper surface of the mounting base plate is provided with a mounting square opening, and the left side of the upper surface of the mounting base plate is provided with a radiator;

the heat exchange mechanism comprises: the heat exchange mechanism is arranged on the right side of the upper surface of the mounting bottom plate, the lower end opening of the heat exchange mechanism corresponds to the mounting square opening, the upper end water inlet of the heat exchange mechanism is communicated with the upper end water outlet of the radiator through a pipeline, and the lower end water outlet of the heat exchange mechanism is communicated with the lower end water inlet of the radiator through a pipeline;

the energy recovery mechanism comprises: set up in the inside left end of installing support, energy recuperation mechanism's upper end and heat transfer mechanism fixed connection can realize the circulative cooling of coolant liquid, utilize the heat flow effect of air to accelerate the heat dissipation of coolant liquid, can generate electricity the difference in temperature that produces when the coolant liquid dispels the heat, realize the recycle of energy, reduce the waste of resource.

Further, heat transfer mechanism is including installation shell, fixed inner shell and heat transfer spiral pipe, installation shell and fixed inner shell all set up in mounting plate's upper surface right side, and fixed inner shell is located the inside of installation shell, and the lower extreme opening of fixed inner shell corresponds with installation square-mouth position, and the heat transfer spiral pipe sets up in the outside of installation shell, and the upper end water inlet of heat transfer spiral pipe passes through the pipeline intercommunication with the upper end delivery port of radiator, and the lower extreme delivery port of heat transfer spiral pipe passes through the pipeline intercommunication with the lower extreme water inlet of radiator, can realize the circulative cooling of coolant liquid.

Further, heat transfer mechanism still includes the water conservancy diversion mouth, the water conservancy diversion mouth sets up in the upper end of installation shell, the top of fixed inner shell and the inside wall body lower extreme fixed connection of water conservancy diversion mouth, and the water conservancy diversion mouth is the little big tubaeform water conservancy diversion mouth of lower extreme in upper end, can improve the air flow rate of below.

Further, energy recuperation mechanism includes thermoelectric generation piece, supporting baffle, installation backing plate and battery, the thermoelectric generation piece sets up in the space that the outside correspondence of installation shell inside and fixed inner shell formed, and the supporting baffle sets up in the left end of installing support, and the installation backing plate sets up in the bottom support body upper surface left side of installing support, and the battery sets up in the upper surface middle part of installation backing plate, and the input of battery is connected to the output electricity of thermoelectric generation piece, can realize the recovery of energy, reduces the wasting of resources.

Further, the heat exchange device further comprises an axial flow fan and a control switch, wherein the axial flow fan is arranged inside the mounting square opening, the control switch is arranged on the front side of the upper surface of the mounting bottom plate, the input end of the control switch is electrically connected with the output end of the storage battery, and the input end of the axial flow fan is electrically connected with the output end of the control switch to guide air to flow, so that the heat exchange efficiency of the upper part is improved.

Compared with the prior art, the beneficial effects of the utility model are that: this novel radiator energy recuperation device has following benefit:

1. after heat generated by external equipment enters the radiator, the heat is absorbed by cooling liquid in the radiator, the cooling liquid absorbing the heat enters the heat exchange spiral pipe through a water outlet at the upper end of the radiator, along with the downward flow of the spiral pipe, in the downward flow process of the cooling liquid, the heat in the radiator is transmitted to the installation outer shell through the spiral pipe and then transmitted to the fixed inner shell through the installation outer shell, and finally transmitted to the air in the middle of the fixed inner shell through the fixed inner shell, so that the heat is dissipated, because the cooling liquid flows downwards along the spiral pipe, the temperature of the upper end and the lower end of the air in the fixed inner shell is high along with the reduction of the temperature of the cooling liquid, according to the heat flow effect of the air, the air can expand after being heated, the relative mass becomes light, and can flow upwards, so that the air in the middle of the fixed inner shell can automatically flow upwards, when passing through the flow guide opening, the air that can make the upflow produces the torrent along with the diminishing of water conservancy diversion mouth upper end opening to this to, air velocity is accelerated, improves heat exchange efficiency, can realize the circulative cooling of coolant liquid, utilizes the heat flow effect of air to accelerate the heat dissipation of coolant liquid.

2. When carrying out the heat transfer to the inside coolant liquid of coil pipe, the thermoelectric generation piece senses the difference in temperature of both sides to utilize the difference in temperature to generate electricity, store the electric energy that produces in the inside of battery afterwards, can generate electricity the difference in temperature that produces when the coolant liquid dispels the heat, make the heat energy of radiator obtain effective utilization, realize the recycle of energy, reduce the waste of resource.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural diagram of the heat exchange mechanism of the present invention.

In the figure: the device comprises a mounting base plate 1, a control switch 2, a mounting support 3, a universal wheel 4, a radiator 5, a square mounting opening 6, a heat exchange mechanism 7, a flow guide opening 71, an outer mounting shell 72, a fixed inner shell 73, a heat exchange spiral pipe 74, an energy recovery mechanism 8, a thermoelectric generation sheet 81, a supporting partition plate 82, a mounting base plate 83, a storage battery 84 and an axial flow fan 9.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution: a novel radiator energy recovery device comprises an installation bottom plate 1, a heat exchange mechanism 7 and an energy recovery mechanism 8;

mounting the bottom plate 1: the mounting bottom plate 1 provides a mounting place for other components, a mounting support 3 is arranged on the lower surface of the mounting bottom plate, the mounting support 3 supports the components above, universal wheels 4 are arranged at four corners of the bottom of the mounting support 3, the universal wheels 4 are convenient for movement of the device, a mounting square opening 6 is formed in the right side of the upper surface of the mounting bottom plate 1, the mounting square opening 6 is convenient for air flow, a radiator 5 is arranged on the left side of the upper surface of the mounting bottom plate 1, and the radiator 5 cools external equipment;

the heat exchange mechanism 7: the heat exchange mechanism 7 can realize circulating cooling of cooling liquid, and is arranged on the right side of the upper surface of the mounting base plate 1, a lower end opening of the heat exchange mechanism 7 corresponds to the position of the mounting square opening 6, an upper end water inlet of the heat exchange mechanism 7 is communicated with an upper end water outlet of the radiator 5 through a pipeline, a lower end water outlet of the heat exchange mechanism 7 is communicated with a lower end water inlet of the radiator 5 through a pipeline, the heat exchange mechanism 7 comprises a mounting outer shell 72, a fixed inner shell 73 and a heat exchange spiral pipe 74, the mounting outer shell 72 and the fixed inner shell 73 are both arranged on the right side of the upper surface of the mounting base plate 1, the fixed inner shell 73 is positioned inside the mounting outer shell 72, a lower end opening of the fixed inner shell 73 corresponds to the position of the mounting square opening 6, the heat exchange spiral pipe 74 is arranged outside the mounting outer shell 72, an upper end water inlet of the heat exchange spiral pipe 74 is communicated with an upper end water outlet of the radiator 5 through a pipeline, and a lower end water outlet of the heat exchange spiral pipe 74 is communicated with a lower end water inlet of the radiator 5 through a pipeline, the heat exchange mechanism 7 further comprises a flow guide opening 71, the flow guide opening 71 is arranged at the upper end of the mounting outer shell 72, the top of the fixed inner shell 73 is fixedly connected with the lower end of the inner wall body of the flow guide opening 71, the flow guide opening 71 is a horn-shaped flow guide opening with a small upper end and a large lower end, heat generated by external equipment is absorbed by cooling liquid in the radiator 5 after entering the radiator 5, the cooling liquid absorbing the heat enters the heat exchange spiral pipe 74 through a water outlet at the upper end of the radiator 5, the internal heat flows downwards along with the spiral pipe 74, in the process of flowing downwards, the internal heat is transferred to the mounting outer shell 72 through the spiral pipe 74, then is transferred to the fixed inner shell 73 through the mounting outer shell 72, and finally is transferred to air in the middle of the fixed inner shell 73 through the fixed inner shell 73, so that heat dissipation is realized, because the cooling liquid flows downwards along the spiral pipe 74, the upper end temperature of the air in the fixed inner shell 73 is high along with the temperature reduction of the cooling liquid, the lower end temperature is low, according to the heat flow effect of the air, the air can expand after being heated, the relative mass becomes light, and therefore the air can flow upwards, so that the air in the middle of the fixed inner shell 73 can automatically flow upwards, and when the air passes through the flow guide opening 71, the air flowing upwards can generate turbulence along with the reduction of the opening at the upper end of the flow guide opening 71, so that the air flow rate is accelerated, and the heat exchange efficiency is improved;

the energy recovery mechanism 8: the energy recovery mechanism 8 can realize energy recovery and reduce resource waste, and is arranged at the left end inside the mounting bracket 3, the upper end of the energy recovery mechanism 8 is fixedly connected with the heat exchange mechanism 7, the energy recovery mechanism 8 comprises a thermoelectric generation piece 81, a supporting partition plate 82, a mounting cushion plate 83 and a storage battery 84, the thermoelectric generation piece 81 is arranged in a space correspondingly formed inside the mounting outer shell 72 and outside the fixed inner shell 73, the supporting partition plate 82 is arranged at the left end of the mounting bracket 3, the mounting cushion plate 83 is arranged at the left side of the upper surface of the bottom frame body of the mounting bracket 3, the supporting partition plate 82 and the mounting cushion plate 83 provide a mounting place for the storage battery 84, the storage battery 84 is arranged in the middle of the upper surface of the mounting cushion plate 83, the energy recovery mechanism further comprises an axial flow fan 9 and a control switch 2, the axial flow fan 9 is arranged inside the mounting square opening 6, and the control switch 2 regulates and controls the axial flow fan 9 to work, the control switch 2 is arranged on the front side of the upper surface of the installation bottom plate 1, when the cooling liquid in the spiral pipe 74 is subjected to heat exchange, the temperature difference generating pieces 81 sense the temperature difference on the two sides, and generates electricity using the difference between high and low temperatures, and then stores the generated electricity in the inside of the storage battery 84, when the heat dissipation efficiency of the heat sink 5 can not meet the requirement of the external device, the axial flow fan 9 works by controlling the switch 2 to guide the ambient air to flow into the fixed inner shell 73, so as to accelerate the air flow rate in the middle of the fixed inner shell 73, further, the heat dissipation of the cooling liquid inside the heat exchange spiral pipe 74 is accelerated, so that the heat dissipation efficiency of the heat sink 5 is improved, the input end of the control switch 2 is electrically connected with the output end of the storage battery 84, the input end of the axial flow fan 9 is electrically connected with the output end of the control switch 2, and the output end of the thermoelectric generation piece 81 is electrically connected with the input end of the storage battery 84.

When in use: the radiator energy recovery device is pushed to a use position, the universal wheel 4 is locked, the radiator energy recovery device is fixed in the use position, a heat exchange port of external equipment is communicated with the radiator 5, the installation of the device is completed, heat generated by the external equipment is absorbed by cooling liquid in the radiator 5 after entering the radiator 5, the cooling liquid absorbing the heat enters the heat exchange spiral pipe 74 through a water outlet at the upper end of the radiator 5, along with the downward flow of the spiral pipe 74, in the downward flow process of the cooling liquid, the heat in the radiator is transferred to the installation outer shell 72 through the spiral pipe 74, then is transferred to the fixed inner shell 73 through the installation outer shell 72, and finally is transferred to air in the middle of the fixed inner shell 73 through the fixed inner shell 73, so that the heat dissipation is realized, because the cooling liquid flows downwards along the spiral pipe 74, the temperature of the upper end of the air in the fixed inner shell 73 is high along with the reduction of the temperature of the cooling liquid, the lower end temperature is low, according to the heat flow effect of the air, the air will expand after being heated and the relative mass will become light, therefore, the air will flow upwards, so that the air in the middle of the fixed inner shell 73 automatically flows upwards, when passing through the diversion port 71, the upwards flowing air will generate turbulence along with the reduction of the opening at the upper end of the diversion port 71, so as to accelerate the air flow rate and improve the heat exchange efficiency, when the heat exchange is carried out on the cooling liquid in the spiral pipe 74, the temperature difference generating sheet 81 senses the temperature difference at the two sides, and the electricity is generated by using the high and low temperature difference, then the generated electric energy is stored in the storage battery 84, when the heat dissipation efficiency of the radiator 5 can not meet the requirement of external equipment, the axial flow fan 9 works by controlling the switch 2, the surrounding air is guided to flow into the fixed inner shell 73, so as to accelerate the air flow rate in the middle of the fixed inner shell 73, thereby accelerating the heat dissipation of the coolant in the heat exchange coil 74 and improving the heat dissipation efficiency of the heat sink 5.

It should be noted that the axial flow fan 9 disclosed in this embodiment may be an axial flow fan of the type XBDZ of texas air conditioning equipment ltd, and the control switch is provided with a switch button corresponding to the axial flow fan 9 and used for controlling the on-off operation of the axial flow fan.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a novel radiator energy recuperation device which characterized in that: comprises a mounting bottom plate (1), a heat exchange mechanism (7) and an energy recovery mechanism (8);

mounting base plate (1): the lower surface of the mounting plate is provided with a mounting bracket (3), four corners of the bottom of the mounting bracket (3) are provided with universal wheels (4), the right side of the upper surface of the mounting base plate (1) is provided with a mounting square opening (6), and the left side of the upper surface of the mounting base plate (1) is provided with a radiator (5);

heat exchange mechanism (7): the heat exchanger is arranged on the right side of the upper surface of the mounting bottom plate (1), the lower end opening of the heat exchange mechanism (7) corresponds to the mounting square opening (6), the upper end water inlet of the heat exchange mechanism (7) is communicated with the upper end water outlet of the radiator (5) through a pipeline, and the lower end water outlet of the heat exchange mechanism (7) is communicated with the lower end water inlet of the radiator (5) through a pipeline;

energy recovery mechanism (8): the energy recovery mechanism is arranged at the left end inside the mounting bracket (3), and the upper end of the energy recovery mechanism (8) is fixedly connected with the heat exchange mechanism (7).

2. The novel heat sink energy recovery device of claim 1, wherein: heat exchange mechanism (7) are including installation shell (72), fixed inner shell (73) and heat transfer spiral pipe (74), installation shell (72) and fixed inner shell (73) all set up in the upper surface right side of mounting plate (1), and fixed inner shell (73) are located the inside of installation shell (72), and the lower extreme opening and the installation square mouth (6) position of fixed inner shell (73) correspond, and heat transfer spiral pipe (74) set up in the outside of installation shell (72), and the upper end water inlet of heat transfer spiral pipe (74) passes through the pipeline intercommunication with the upper end delivery port of radiator (5), and the lower extreme delivery port of heat transfer spiral pipe (74) passes through the pipeline intercommunication with the lower extreme water inlet of radiator (5).

3. The novel heat sink energy recovery device of claim 2, wherein: the heat exchange mechanism (7) further comprises a flow guide opening (71), the flow guide opening (71) is formed in the upper end of the mounting outer shell (72), the top of the fixed inner shell (73) is fixedly connected with the lower end of the inner wall body of the flow guide opening (71), and the flow guide opening (71) is a horn-shaped flow guide opening with a small upper end and a large lower end.

4. The novel heat sink energy recovery device of claim 2, wherein: energy recuperation mechanism (8) are including thermoelectric generation piece (81), support baffle (82), mounting pad board (83) and battery (84), thermoelectric generation piece (81) set up in the space of installing inside and fixed inner shell (73) outside correspondence formation of shell (72), and support baffle (82) set up in the left end of installing support (3), and mounting pad board (83) set up in the bottom support body upper surface left side of installing support (3), and battery (84) set up in the upper surface middle part of mounting pad board (83), and the input of battery (84) is connected to the output electricity of thermoelectric generation piece (81).

5. The novel heat sink energy recovery device of claim 4, wherein: the novel fan is characterized by further comprising an axial flow fan (9) and a control switch (2), wherein the axial flow fan (9) is arranged inside the mounting square opening (6), the control switch (2) is arranged on the front side of the upper surface of the mounting bottom plate (1), the input end of the control switch (2) is electrically connected with the output end of the storage battery (84), and the input end of the axial flow fan (9) is electrically connected with the output end of the control switch (2).

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