CN211575594U - Neural network radiation plate based on semiconductor refrigeration and heating principle - Google Patents

Neural network radiation plate based on semiconductor refrigeration and heating principle Download PDF

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Publication number
CN211575594U
CN211575594U CN202020126100.XU CN202020126100U CN211575594U CN 211575594 U CN211575594 U CN 211575594U CN 202020126100 U CN202020126100 U CN 202020126100U CN 211575594 U CN211575594 U CN 211575594U
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China
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semiconductor
heat
neural network
heating
module
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CN202020126100.XU
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Chinese (zh)
Inventor
刘泽勤
杨洋
李�杰
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Tianjin University of Commerce
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Tianjin University of Commerce
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Abstract

The utility model discloses a neural network radiant panel based on semiconductor refrigeration heats principle, including semiconductor work module, semiconductor work module shows through the connected mode of semiconductor heat transfer ware positive negative pole and N, P utmost point difference that one end realizes refrigerating and heating for the hot junction for the cold junction other end, including a plurality of semiconductor heat transfer ware that link together with the same journey with an electric wire, semiconductor heat transfer ware presss from both sides in the middle of the thermal insulation layer, and the thermal insulation layer is through decurrent heat pipe connection radiant panel. The utility model discloses a semiconductor heat transfer ware adopts the design of distributing with the form to be covered with indoor top, can realize heating the indoor human refrigeration, convenient control.

Description

Neural network radiation plate based on semiconductor refrigeration and heating principle
Technical Field
The utility model relates to a semiconductor refrigeration heats technical field, especially relates to neural network radiation board based on semiconductor refrigeration heats the principle.
Background
The harm of Freon is serious, is the 'fierce' that destroys the ozone layer, and the urgent need changes this kind of traditional heating refrigeration mode, and traditional air conditioner does not have the difference heating refrigeration to whole room in addition, and the human body is not got perfect comfortable experience of body surface temperature, still can cause very big degree energy waste. Therefore, a new refrigeration and heating method is urgently needed to change the traditional refrigeration and heating mode which pollutes the environment and wastes energy.
SUMMERY OF THE UTILITY MODEL
The utility model aims at the technical defects in the prior art, and provides a neural network radiation plate based on the semiconductor refrigeration and heating principle, which is used for indoor refrigeration and heating of human body, does not use refrigerant and is beneficial to protecting environment, and intelligently adjusts power and is beneficial to saving energy; only the heat transmitter and the anode-cathode conversion device are needed to realize heat supply in winter and refrigeration in summer.
For realizing the utility model discloses a technical scheme that the purpose adopted is:
a neural network radiation plate based on a semiconductor refrigerating and heating principle comprises a semiconductor working module, wherein the semiconductor working module shows that one end of the semiconductor working module is a cold end and the other end of the semiconductor working module is a hot end through different connection modes of the anode and the cathode of a semiconductor heat transfer device and N, P poles, the neural network radiation plate comprises a plurality of semiconductor heat transfer devices which are connected together in a same-stroke mode through a wire, the semiconductor heat transfer devices are clamped in a heat-insulating layer, and the heat-insulating layer is connected with a radiation plate through downward heat pipes.
And the system control module is connected with the semiconductor working module through an electric wire and comprises an intelligent control display, and a positive-negative switching device of the semiconductor heat transmitter is integrated in the intelligent control display so as to realize switching of the refrigeration and heating modes.
Furthermore, the intelligent control display is provided with an operation display screen, wherein the operation display screen is used for the conversion operation of the refrigeration and heating modes and the opening and closing operation of the power state of each semiconductor heat exchanger, namely the automatic working mode of opening and closing the heat transmitter.
Furthermore, the system control module is connected with the monitoring module and used for monitoring the specific position of a human body in a room, monitoring information is transmitted to the intelligent control display of the system control module, and the intelligent control display controls the semiconductor module according to the monitoring information.
Preferably, the monitoring module comprises four infrared detectors arranged at four corners of the top of the room to detect and determine the position of each person in the room.
The utility model discloses a semiconductor heat transfer ware adopts the design of distributing with the form to be covered with indoor top, can realize heating the indoor human refrigeration, convenient control.
In addition, the infrared detector is used for detecting the position of a human body, and the power of the semiconductor at the position is correspondingly changed through the intelligent control display, so that the aims of energy conservation and emission reduction can be fulfilled.
Drawings
Fig. 1 is a schematic diagram of a neural network radiation plate based on the principle of semiconductor cooling and heating;
FIG. 2 is a schematic sectional view of an installation of a single semiconductor heat spreader;
fig. 3 is an exploded view of the installation of a single semiconductor heat spreader.
In the figure: 1-32 are all semiconductor heat transmitters; 33-a first infrared detector; 37-a second infrared detector; 38-a third infrared detector; 39-fourth infrared detector; 35-an electrical wire; 36-heat preservation and insulation layer; 40-an intelligent control display; 41-operating the display screen; 42-upward heat pipes (i.e., toward the roof); 36-heat preservation and insulation layer; 43-heat pipes downward (i.e., toward the room); 44-radiation plate.
Detailed Description
The present invention will be described in further detail with reference to the following drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
As shown in fig. 1, the utility model discloses neural network radiation board based on semiconductor refrigeration heats principle, include:
the semiconductor working module shows that one end is a cold end and the other end is a hot end through different connection modes of the anode and the cathode of a semiconductor heat transmitter and N, P to realize refrigeration and heating, and comprises a plurality of semiconductor heat transmitters (1, 2, 3-31 and 32), a heat insulation layer 36 is made of ZS-1 high-temperature-resistant heat insulation materials, the upper surface and the lower surface of each semiconductor heat transmitter are provided with a downward heat pipe 43 and an upward heat pipe 42, the semiconductor heat transmitters are clamped in the middle of the heat insulation layer 36, the heat insulation layer 36 is connected with a radiation plate 44 through the downward heat pipe 43, and the heat insulation layer prevents the cold end and the hot end of each semiconductor heat transmitter from mutually offsetting energy. The radiation plate 44 can be made of aluminum alloy, and the surface of the radiation plate is coated with infrared radiation material, namely carbon fiber products, so that heat energy can be better transmitted to a human body. The downward heat pipes 43 are to prevent the ceramic, which is the internal insulator of the semiconductor heat spreader, from being burned out when the upper end of the heat pipes in summer is used as the hot end, so that the downward heat pipes 43 can conduct heat to the radiation plate when the lower portion of the heat pipes in winter is used as the hot end to dissipate heat.
The semiconductor heat exchanger is provided with two stages of couples, one end of the couple is a hot end, the other end of the couple is a cold end, in winter, the positive electrode is connected with the P stage to enable the surface facing the indoor to be the hot end, and the negative electrode is connected with the N stage to enable the surface facing the roof to be the cold end; in summer, the opposite is realized, and through the positive and negative electrode switching/conversion switch/device, the positive electrode is connected with the N-stage to enable the surface facing the indoor to be used as the cold end, and the negative electrode is connected with the P-stage to enable the surface facing the roof to be used as the hot end. The semiconductor working module can realize the anode and cathode conversion control through the connected anode and cathode conversion devices, and can be manually controlled or automatically controlled.
It should be noted that, because the heat generated at the hot end of the semiconductor heat spreader is too large, a radiator must be provided for heat dissipation, so the upper and lower surfaces of the semiconductor heat spreader are connected with a plurality of heat pipes, and the connection of the downward heat pipe and the radiation plate can transfer the heat of the semiconductor heat spreader to the radiation plate and transfer the heat to the radiation plate with a larger area, thereby avoiding the device from being burned out and transferring the heat to the human body.
In one embodiment, a plurality of semiconductor heat sinks are connected by wires 35 in the manner shown in fig. 1, and all semiconductor heat sinks are connected by a single wire to an intelligent control display 40 for controlling and changing the power level of the heat sinks.
The power and the quantity of the semiconductor heat transmitter, namely the semiconductor refrigeration piece, are determined by the cold and heat load and the space size of a specific use scene.
The intelligent control display 40 is internally integrated with a positive-negative switching device of the semiconductor heat transmitter, can switch a winter-summer cooling and heating mode and is used for manually switching the working state of winter and summer; the operation display 41 can operate two aspects, namely, the conversion of the cooling and heating modes, and the turning on and off of the power state of each semiconductor heat exchanger, namely, the automatic working mode of turning on and off the heat transmitter.
Further, the intelligent control display 40 is connected with a monitoring module (infrared detector), the monitoring module (infrared detector) detects the specific indoor position of the human body, information is transmitted to the intelligent control display 40, accordingly, the power of the semiconductor heat transmitter in the area is intelligently controlled and improved, and other unmanned area semiconductor heat transmitters are closed.
The monitoring module comprises a first infrared detector 33, a second infrared detector 37, a third infrared detector 38 and a fourth infrared detector 39, is connected with the intelligent control display 40 through electric wires, detects the specific indoor position of the human body, and transmits information to the intelligent control display 40. The infrared detectors are arranged at the four corners of the top of the room as required, so that the position of each person in the room can be accurately determined, and the infrared detectors are used for monitoring the specific position of the human body in the room, as shown in fig. 1.
Further, in order to achieve humanization, the intelligent control display 40 should display the working status of all semiconductor heat exchangers, i.e. whether to start the automatic working status of the heat exchangers, and the indoor personnel can feel the automatic working status of the switches according to their own body, and the command of the intelligent control display 40 is the first command of the system. When the indoor personnel do not want to open the heat exchanger automatically, the automatic working mode of the heat exchanger can be closed, and meanwhile, the automatic working mode of the heat exchanger can be opened manually.
When the infrared detector is installed and used, the semiconductor heat transfer device is connected and distributed at the indoor top in the same form and is connected to an intelligent control display together, when the infrared detector detects a human body, information is transferred to the intelligent control display, and then the power of the semiconductor heat exchanger at the corresponding position is changed. The intelligent control display can be used for manually starting or stopping the heat transmitter to start the automatic working state.
The utility model discloses a "neural network" radiation plate based on semiconductor refrigeration heats principle comes to indoor heat supply refrigeration. 1, the condition that the refrigerant must be used for indoor heating and cooling is changed, and the discharge of the refrigerant is reduced, thereby being beneficial to protecting the environment. And 2, intelligently adjusting the power is beneficial to saving energy, and energy consumed by using a large number of air conditioners is reduced. Finally, the position of the personnel can be automatically detected, the corresponding heat transmitter can be selected to start, and the automatic working mode can be manually closed, so that the device is more convenient and saves energy. And 3, only the heat transmitter and the positive-negative electrode conversion device are needed to realize heat supply in winter and refrigeration in summer.
The utility model discloses can be applied to office, meeting room of general size, this utility model does not have the refrigerant emission problem and accomplishes the environmental protection, also can intelligent regulation power realize energy-conserving purpose.
The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (5)

1. The neural network radiation plate based on the semiconductor refrigerating and heating principle is characterized by comprising a semiconductor working module, wherein the semiconductor working module shows that one end of the semiconductor working module is a cold end and the other end of the semiconductor working module is a hot end through different connection modes of the anode and the cathode of a semiconductor heat transmitter and N, P poles, the neural network radiation plate realizes refrigerating and heating and comprises a plurality of semiconductor heat transmitters which are connected together in a same-way mode through one electric wire, the semiconductor heat transmitters are clamped in the middle of a heat-insulating layer, and the heat-insulating layer is connected with the radiation plate through downward heat.
2. The neural network radiation plate based on the semiconductor cooling and heating principle as claimed in claim 1, further comprising a system control module connected with the semiconductor working module through a wire, wherein the system control module comprises an intelligent control display, and a positive-negative switching device of a semiconductor heat transmitter is integrated in the intelligent control display so as to realize switching of the cooling and heating modes.
3. The neural network radiation panel based on the semiconductor cooling and heating principle according to claim 2, wherein the intelligent control display is provided with an operation display screen, the operation display screen is used for the switching operation of the cooling and heating mode, and the automatic operation mode is used for the on-off operation of the power state of each semiconductor heat exchanger, namely, the on-off operation of the heat transmitter.
4. The neural network radiation panel based on the semiconductor cooling and heating principle according to claim 2 or 3, wherein the system control module is connected with the monitoring module, and is used for monitoring the specific position of the human body in the room, transmitting the monitoring information to the intelligent control display of the system control module, and controlling the semiconductor module by the intelligent control display according to the monitoring information.
5. The neural network radiation panel based on semiconductor cooling and heating principle of claim 4, characterized in that, the monitoring module comprises four infrared detectors arranged at four corners of the top of the room to detect and determine the position of each person in the room.
CN202020126100.XU 2020-01-19 2020-01-19 Neural network radiation plate based on semiconductor refrigeration and heating principle Expired - Fee Related CN211575594U (en)

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CN202020126100.XU CN211575594U (en) 2020-01-19 2020-01-19 Neural network radiation plate based on semiconductor refrigeration and heating principle

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111141058A (en) * 2020-01-19 2020-05-12 天津商业大学 Neural network radiation plate based on semiconductor refrigeration and heating principle

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111141058A (en) * 2020-01-19 2020-05-12 天津商业大学 Neural network radiation plate based on semiconductor refrigeration and heating principle

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CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20200925

Termination date: 20210119

CF01 Termination of patent right due to non-payment of annual fee