CN218832032U - Semiconductor refrigeration wearable device and air conditioning suit thereof - Google Patents

Abstract

A wearable device for semiconductor refrigeration and an air conditioning suit thereof belong to the technical field of wearable devices. The intelligent temperature control and display device comprises a temperature intelligent control and display part 21, a chest internal refrigeration and energy storage circulation assembly 23, a back internal refrigeration and energy storage circulation assembly 22, a host machine, a battery pack backpack 20 and the like; the wearable device for semiconductor refrigeration is arranged in the coat; the temperature intelligent control and display component (21) is arranged outside the chest of the coat; the back internal refrigeration and energy storage cycle assembly (22) is arranged inside the back of the coat; the lithium battery pack (19) is connected with the time cycle on-off module (18) and the like. The utility model discloses a semiconductor refrigeration piece, refrigeration conduction piece, water receiver, lithium cell group etc. technique can obtain lightly, nice and graceful, the semiconductor refrigeration that refrigeration effect is high and can exchange refrigeration system and clothing (air conditioner clothes) with two in actual life and work, has positive market prospect.

Description

Semiconductor refrigeration wearable device and air conditioning suit thereof

Technical Field

The utility model relates to a refrigerated wearable device of semiconductor and air conditioner clothes thereof especially relates to a semiconductor refrigeration technology and dual energy exchange lithium cell charging cooling refrigerated remove wearable clothing's device, belongs to rechargeable battery group and solar rechargeable battery group power supply semiconductor refrigeration device and clothing technical field.

Background

In daily life, people live and work outdoors in summer in a high-temperature environment without commercial power air conditioning equipment, and a portable refrigeration mode is still blank. Although some fans with batteries are embedded in the clothes, the convection effect of the traditional high-temperature air is only used. The effect is not good, and no air conditioning system is in the true sense. And a refrigeration mode of a vehicle-mounted compressor is occasionally available, and due to the metal property of the compressor, the weight is large, the energy consumption of the compressor is very large, and a portable, low-energy-consumption and sustainable refrigeration system is difficult to form. Therefore, the semiconductor refrigeration and dual-energy interchange refrigeration system which is light, beautiful and high in refrigeration effect is very important in actual life and work.

The inventor mentions a cooling device in a solar refrigerating device (patent number: 201620148254.2) for covering or fixing a space on a vehicle body, which comprises a solar panel, a lithium rechargeable battery, a first main circuit water receiver, a second water receiver, a semiconductor refrigerating sheet, a hot end radiator, a cold end radiator and a heat insulation layer, wherein the solar panel and the lithium battery pack provide 12V direct current voltage to enable the circuit to work; it is stated that the bubbles and ultrasonic energy in the first and second reservoirs take away heat.

Moreover, in the living environment with high temperature in summer, people are inconvenient in any refrigeration mode of wired power supply in a mobile state, and even cannot implement the refrigeration mode.

SUMMERY OF THE UTILITY MODEL

As described in the background, the applicant hopes to realize a wearable air conditioning device implanted garment capable of wearing a lithium battery on the body and being conveniently charged at high temperature in summer, and innovates a wearable air conditioning garment. This is a system that is difficult to match and complex to operate. The applicant obtains the following technical scheme through long-term research, multiple experiments and repeated comparison and test:

the technical scheme of the utility model is that:

a wearable device for semiconductor refrigeration comprises a temperature intelligent control and display part 21, a chest internal refrigeration and energy storage circulation assembly 23, a waterway circulation pipe, a power transmission circuit and a surface heat insulation layer 24 thereof, a back internal refrigeration and energy storage circulation assembly 22, a host and a battery pack backpack 20;

the temperature intelligent control and display part 21 comprises an intelligent temperature control and display module 17;

the front chest refrigeration and energy storage circulating assembly 23 comprises a first water cooling block 8, a first semiconductor refrigeration sheet 9, a first heat insulation layer 10, a first refrigeration conduction sheet 11, a second polymer cold storage 25 and a first polymer cold storage 26;

the waterway circulation pipe, the power transmission circuit and the surface heat-insulating layer 24 thereof comprise a water pipe pipeline, an electric wire and the surface heat-insulating layer thereof;

the back internal refrigeration and energy storage circulating assembly 22 comprises a temperature feedback device 12, a second refrigeration conducting piece 13, a second heat insulation layer 14, a second semiconductor refrigeration piece 15 and a second water cooling block 16;

the main machine and battery pack backpack 20 comprises a first water storage device 1, a second water storage device 2, a first electromagnetic valve 3, a first self-sucking pump 4, an air pump 5, a second self-sucking pump 6, a second electromagnetic valve 7, a time cycle on-off module 18, a lithium battery pack 19, a first one-way exhaust valve 27, a second one-way exhaust valve 28, a first sand oxygen head 30 and a second sand oxygen head 31;

the lithium battery pack 19 is connected with the time cycle on-off module 18;

the time cycle on-off module 18 is connected with the intelligent temperature control and display module 17, the first semiconductor refrigerating sheet 9, the first water cooling block 8, the second semiconductor refrigerating sheet 15, the second water cooling block 16, the first electromagnetic valve (3), the first self-priming pump 4, the air pump 5, the second self-priming pump 6 and the second electromagnetic valve 7;

the intelligent temperature control and display module 17 is connected with the temperature feedback device 12;

the upper surface of the first semiconductor refrigeration chip 9 generates cold energy; the upper surface of the first semiconductor refrigeration sheet 9 is connected with a first polymer refrigeration storage 26, and the first polymer refrigeration storage 26 is connected with a first refrigeration conduction sheet 11; the part of the first polymer refrigeration storage 26, which is not in contact with the upper surface of the first semiconductor refrigeration sheet 9, is connected with the first heat insulation layer 10; the lower surface of the first semiconductor refrigeration sheet 9 is bonded and connected with the first water cooling block 8 by heat-conducting silica gel;

the first water cooling block 8 is an aluminum alloy water cooling block and internal circulating water (normal temperature purified water or ethanol-based heat-conducting liquid)

The first water cooling block 8 is connected with a first electromagnetic valve 3, a first self-priming pump 4, a second self-priming pump 6 and a second electromagnetic valve 7 through water pipelines;

the first electromagnetic valve 3 and the first self-priming pump 4 are respectively connected with the first water storage device 1 through water pipelines;

the second electromagnetic valve 7 and the second self-priming pump 6 are respectively connected with the second water receiver 2 through water pipelines;

the first reservoir 1 contains a first one-way outlet valve 27;

the second reservoir 2 contains a second one-way vent valve 28;

the air pump 5 is respectively connected with the first water storage device 1 and the second water storage device 2 through a pipeline and a first oxygen sand head 30 and a second oxygen sand head 31;

the upper surface of the second semiconductor chilling plate 15 generates cooling energy; the upper surface of the second semiconductor refrigeration piece 15 is connected with a second polymer refrigeration storage 25, and the second polymer refrigeration storage 25 is connected with a second refrigeration conduction piece 13;

the second refrigeration conducting sheet 13 is in contact with the temperature feedback device 12, and the contact part of the second polymer refrigeration storage 25 and the upper surface of the second semiconductor refrigeration sheet 15 is not connected with the second heat insulation layer 14; the lower surface of the second semiconductor refrigerating sheet 15 is bonded with a second water cooling block 16 by heat-conducting silica gel; the second water cooling block 16 is an aluminum alloy water cooling block, and internal circulating water (normal-temperature purified water or ethanol-based heat-conducting liquid) in the second water cooling block 16 is connected with the first electromagnetic valve 3, the first self-sucking pump 4, the second self-sucking pump 6 and the second electromagnetic valve 7 through water pipelines;

the first electromagnetic valve 3 and the first self-priming pump 4 are respectively connected with the first water storage device 1 through water pipelines;

the second electromagnetic valve 7 and the second self-priming pump 6 are respectively connected with the second water receiver 2 through water pipelines;

the first reservoir 1 contains a first one-way outlet valve 27;

the second reservoir 2 contains a second one-way vent valve 28;

the first water reservoir 1 and the second water reservoir 2 contain circulating water (normal temperature purified water or ethanol-based heat transfer fluid).

The temperature intelligent control and temperature display module 17 and the time cycle on-off module 18 can be temperature intelligent control and temperature display modules and time cycle on-off modules adopted by various series refrigerators.

The utility model also provides an air conditioner clothes, this air conditioner clothes is: the wearable device with the semiconductor refrigeration function is arranged in the coat of the garment, and,

the temperature intelligent control and display component 21 is arranged outside the chest of the coat;

the chest refrigeration and energy storage cycle assembly 23 is mounted inside the chest of the garment coat;

the back internal refrigeration and energy storage cycle assembly 22 is mounted inside the back of the garment coat;

the host and battery pack backpack 20 is mounted on the outside of the back of the garment coat;

the water path circulation pipe, the power transmission circuit and the surface heat insulation layer 24 thereof are arranged in the garment upper garment, between the chest internal refrigeration and energy storage circulation assembly 23 and the back internal refrigeration and energy storage circulation assembly 22.

The utility model discloses a working method (method) does: the wearable air-conditioning clothes complete machine operates as shown in figure 1, a lithium battery pack 19 outputs 12V 6AH current to a time cycle on-off module 18, so that a first semiconductor refrigerating sheet 9 and a second semiconductor refrigerating sheet 15 (the first semiconductor refrigerating sheet 9 and the second semiconductor refrigerating sheet 15 are 40mm (millimeter) -40 mm (millimeter) and 36w (watt) respectively, and 12703 semiconductor refrigerating sheets) generate refrigerating effect, cold energy generated on the upper surfaces of the first semiconductor refrigerating sheet 9 and the second semiconductor refrigerating sheet 15 is filled into clothes, so that the periphery of a human body is efficiently refrigerated, and the refrigerating energy is uniformly dispersed through a first refrigerating conduction sheet 11 and a second refrigerating conduction sheet 13, namely red copper (the thickness is 0.5 mm), so that the human body generates normal, comfortable and mild refrigerating effect. Meanwhile, the polymer thermal insulation layers of the first thermal insulation layer 10 and the second thermal insulation layer 14 { the aerogel thermal insulation layers (the thermal conductivity coefficient is 0.018W/(m · K) at normal temperature and 0.009W/(m · K) at low temperature) } prevent cold energy from being conducted to the outside of the clothes. Similarly, the heating energy generated on the lower surfaces of the first semiconductor refrigerating sheet 9 and the second semiconductor refrigerating sheet 15 is conducted out through the first aluminum alloy water cooling block 8 and the second aluminum alloy water cooling block 16 bonded by the heat-conducting silica gel and the internal circulating water (normal-temperature purified water or ethanol-based heat-conducting liquid). One of the characteristics of the semiconductor refrigerating sheet is that the heat generation coefficient is larger than 1, so that efficient heat circulation and rapid heat discharge in the water-based liquid to the outside of a body are required to ensure high refrigerating efficiency. Therefore, the utility model discloses except using the normal atmospheric temperature water base liquid in first water receiver 1 and the second water receiver 2 with first self priming pump 412v 200ma) and second self priming pump 6 (12v.200ma) in turn, fill the normal atmospheric temperature air with high-pressure air pump 5 (12V 400ma tolerance 5L/minute) and cool down in the circulating fluid uninterruptedly simultaneously, and produce numerous micro-bubbles in the twinkling of an eye with first sand oxygen head 25 and second sand oxygen head 26 (and sand oxygen air bubblet) and make normal atmospheric temperature air and take hot water base liquid area of contact increase greatly, increase heat exchange efficiency, make the quick cooling of circulating coolant liquid; the heat exchange efficiency of the refrigeration sheet is enhanced. While the refrigeration and heat rejection cycles operate efficiently. And the time cycle on-off module IC18 controls the first self-sucking pump 4 and the second self-sucking pump 6 to be alternately switched on and off at intervals of on-off (6 minutes). When the water-based liquid in the first water receiver 1 works, the water-based liquid in the second water receiver 2 has a rest and is cooled in the normal-temperature bubble circulation pushing generated by the high-pressure air pump 5, and the hot gas is discharged out of the body through the one-way exhaust valve 27 and the one-way exhaust valve 28. Therefore, the heat exchange efficiency is greatly improved by the alternate work. While the refrigeration and heat discharge high-efficiency operation is carried out, the temperature intelligent control and temperature display (CPU) 17 acquires temperature sensing and feedback signals through the temperature feedback device 12, and the temperature intelligent control and temperature display (CPU) 17 processes and adjusts the temperature to the refrigeration control regulation range of 18-28 ℃. Once the temperature is lower than 18 ℃, the host stops refrigerating through a CPU instruction, and when the temperature exceeds 28 ℃, the host starts refrigerating, so that the refrigerating can always operate in a comfortable range of a human body. In addition, the characteristic of rapid refrigeration of the semiconductor can lead the refrigeration surface of the refrigeration piece to be rapidly reduced to below 0 ℃. Although the average temperature rise by the first and second refrigeration conducting pieces 11 and 13 may still be below 10 c within several tens of seconds. The utility model discloses the back at refrigeration conduction piece has bonded the built-in ice crystal that is made by PE and is the soluble high polymer of polyacrylic acid sodium or polyvinyl alcohol or polyacrylamide, (the characteristic of this kind of material is that the freezing point is less than water (about-12 degrees), aqueous solution proportion is 1 about 10), remove the required cold energy of health refrigeration in the host computer operating time, store in PE ice crystal polymer memory bank with unnecessary refrigeration energy, with the host computer still provides sufficient cold energy and supply the health cooling under non-operating condition, save lithium electricity power consumption (energy-conserving scheme) so promptly, can guarantee the refrigeration of physics and the high valence of energy storage between two refrigeration alternate effect again, accomplish the innovation working scheme of dual energy interchange.

The utility model discloses an air conditioner clothes structure (overall arrangement): a temperature intelligent control display module (CPU) 17 and a PC shell assembly thereof are located in a switch control system at the front upper right corner of a jacket chest, a refrigeration and cold storage circulation assembly (11 +10+8+9+ 26) is located in the front chest right side to form an independent refrigeration unit, a second refrigeration unit is formed by the refrigeration and cold storage circulation assembly (25 +13+14+15+16+ 12) in the back inner part, a second refrigeration unit is connected with a surface heat insulation layer 24 through water circulation and circuit power transmission, and the rest of the structure is entirely located in a main computer bag outside the back.

The utility model has the advantages that:

1. the utility model provides a refrigerated wearable device of semiconductor and air conditioner clothes thereof gives people in daily life (if, people summer in outdoor work), does not have under the commercial power air conditioning equipment condition, refrigerating plant that can hand-carry, the air conditioner clothes that contains wearable device, light, good-looking, refrigeration effect height.

2. The utility model discloses a semiconductor refrigeration, simple structure, light, with low costs, efficient.

3. The utility model adopts a double-energy interchange structure, is light and convenient, has high efficiency and better market application prospect; the utility model relates to a semiconductor refrigeration, ice crystal storage energy storage to and the refrigeration device that charges that exchanges of two water sources intellectuality. The device comprises a lithium battery charging part, a solenoid valve controller, a water pump water supply part, an air pump air circulation part, an intelligent temperature control part, an ice crystal storage cold storage, a cold end heat dissipation water cooling block, a semiconductor refrigerating piece part, a time cycle working circuit, a water storage I, a water storage II, a hot end radiator, a cold end radiator, a heat insulation layer structure and the like; the bubbles and the ultrasonic energy in the first water storage device and the second water storage device take away heat; because the semiconductor refrigeration can make the heat production energy be greater than the refrigeration energy, it is necessary for the heat produced by heat-radiating end to be effectively circulated into the air outside body, and does not produce heat accumulation and heat accumulation, so that said equipment adopts the method of using double water storage devices alternatively and adopts air full-stroke water circulation, and uses sand-oxygen bubbling process in water, so that when the air is passed through the water, the heat contact and heat exchange area of external cold air and circulating water can be greatly raised, so that the heat can be effectively discharged into the space outside body, and the refrigeration efficiency of cold end of semiconductor can be greatly raised. Quickly reducing the temperature to below-10 ℃ in about 10 seconds. In order to effectively utilize the refrigerating capacity, the process is implemented in two aspects, on one hand, in order to prevent the refrigerating capacity from being too low temperature, 0.5mm red copper sheets (220mm X120mm and 40mm X40mm) are adopted for refrigerating sheets, and heat conduction silica gel is used for tightly adhering the refrigerating sheets, so that the ultralow temperature is uniformly diffused on the red copper sheets to uniformly diffuse the cold temperature, and the refrigerating effect which is comprehensive and comfortable for people is achieved. Meanwhile, about 80 grams of ice crystals, namely sodium polyacrylate or polyvinyl alcohol or polyacrylamide soluble high polymer, are filled in the PE refrigeration box on the back of the red copper, and the material has the characteristics that the freezing point is lower than water and about-12 ℃, so that a large amount of heat needs to be absorbed during melting to achieve the refrigeration effect), so that the low-temperature redundant energy for rapidly refrigerating the refrigeration semiconductor is stored in the ice box, and enough cold energy is provided to keep the cool state around the body in the air-conditioning clothes during the period that the main machine stops working before the intelligent temperature of the CPU reaches the high-temperature setting threshold value. Therefore, the stable and continuous operation of refrigeration energy is ensured, and the intermittent energy-saving effect of the lithium battery pack is also ensured. So as to achieve the realization of the energy-saving scheme.

4. The utility model discloses a rechargeable cooling refrigeration mode, under the life environment of high temperature in summer, people have avoided the inconvenient (can't implement even) of the refrigeration mode of wired power supply under the mobile state. The utility model discloses can adopt embodiments such as 6V semiconductor refrigeration piece and 24V semiconductor refrigeration piece and 36V refrigeration piece, only need be equipped with different lithium cell charging group, demonstrate the difference that the refrigerating output is little big-middle-sized. The individual difference, the weight and the refrigeration efficiency can be comprehensively considered, and the matching of the semiconductor refrigeration sheet and the lithium battery pack can be selected, so that the refrigeration effect and the weight of the device are better.

In a word, the utility model discloses a semiconductor refrigeration piece, refrigeration conduction piece, water receiver, lithium cell group etc. technique obtains a semiconductor refrigeration and can exchange wearable device and clothing (promptly, air conditioner clothes) of refrigeration system with two, can lightly, look good at, refrigeration effect height in actual life and work, has positive market prospect.

Drawings

Fig. 1 is a schematic structural view of a wearable device (whole) for semiconductor refrigeration according to the present invention.

Fig. 2 is a schematic diagram of a front structure of an air conditioning suit according to the present invention.

Fig. 3 is a schematic diagram of the back structure of the air conditioning suit of the present invention.

Fig. 4 is a schematic view of the unfolding structure of the air conditioning suit (inside).

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. The drawings and detailed description are to be regarded as illustrative in nature and not as restrictive. Based on the utility model discloses an equivalent replacement is all within the protection scope of the utility model.

The utility model provides a wearable air conditioner clothes of portable removal refrigeration of semiconductor refrigeration dual energy alternate cold energy of lithium cell group power supply. Fig. 1 is a schematic structural view of the wearable device (whole) for semiconductor refrigeration according to the present invention. In the figure, 1 is a first water reservoir; 2 is a second water receiver; 3 is a first electromagnetic valve; 4 is a first self-priming pump; 5, an air pump, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 17, 18 and 19 are respectively arranged in a vacuum chamber, wherein the vacuum chamber is provided with a first heat insulation layer, a first refrigeration conduction sheet, a temperature feedback device, 13, 14, 16, 17, 18 and 19, respectively, and the vacuum chamber is provided with a second refrigeration conduction sheet, a second heat insulation layer, a second refrigeration conduction sheet, a second water cooling block, an intelligent temperature control and display module, a time cycle on-off module and a lithium battery pack; 20 is a host and a battery pack backpack, 21 is a temperature intelligent control and display module, 22 is a back internal refrigeration and energy storage circulation assembly, 23 is a chest internal refrigeration and energy storage circulation assembly, and 24 is a water path circulating pipe, a power transmission circuit and a surface heat insulation layer thereof; 25 is a second polymer refrigeration storage, 26 is a first polymer refrigeration storage, 27 is a first one-way exhaust valve, 28 is a second one-way exhaust valve, 30 is a first sand oxygen head, and 31 is a second sand oxygen head; arrows in the figure indicate signal lines. As shown in fig. 1, a wearable device with semiconductor refrigeration comprises an intelligent temperature control and display part 21, a chest interior refrigeration and energy storage circulation assembly 23, a waterway circulation pipe, a power transmission circuit and its surface heat insulation layer 24, a back interior refrigeration and energy storage circulation assembly 22, a host and a battery pack backpack 20; the temperature intelligent control and display part 21 comprises an intelligent temperature control and display module 17; the front chest refrigeration and energy storage circulating assembly 23 comprises a first water cooling block 8, a first semiconductor refrigeration sheet 9, a first heat insulation layer 10, a first refrigeration conduction sheet 11, a second polymer cold storage 25 and a first polymer cold storage 26; the waterway circulating pipe, the power transmission circuit and the surface heat-insulating layer 24 thereof comprise a water pipe, an electric wire and the surface heat-insulating layer thereof; the back internal refrigeration and energy storage circulating assembly 22 comprises a temperature feedback device 12, a second refrigeration conducting piece 13, a second heat insulation layer 14, a second semiconductor refrigeration piece 15 and a second water cooling block 16; the main machine and battery pack backpack 20 comprises a first water storage device 1, a second water storage device 2, a first electromagnetic valve 3, a first self-sucking pump 4, an air pump 5, a second self-sucking pump 6, a second electromagnetic valve 7, a time cycle on-off module 18, a lithium battery pack 19, a first one-way exhaust valve 27, a second one-way exhaust valve 28, a first sand oxygen head 30 and a second sand oxygen head 31; the lithium battery pack 19 is connected with the time cycle on-off module 18; the time cycle on-off module 18 is connected with the intelligent temperature control and display module 17, the first semiconductor refrigerating sheet 9, the first water cooling block 8, the second semiconductor refrigerating sheet 15, the second water cooling block 16, the first electromagnetic valve (3), the first self-priming pump 4, the air pump 5, the second self-priming pump 6 and the second electromagnetic valve 7; the intelligent temperature control and display module 17 is connected with the temperature feedback device 12; the upper surface of the first semiconductor refrigeration chip 9 generates cold energy; the upper surface of the first semiconductor refrigeration sheet 9 is connected with a first polymer refrigeration storage 26, and the first polymer refrigeration storage 26 is connected with a first refrigeration conduction sheet 11; the first polymer refrigeration storage 26 is not connected with the first heat insulation layer 10 at the contact part of the upper surface of the first semiconductor refrigeration sheet 9; the lower surface of the first semiconductor refrigeration sheet 9 is bonded and connected with the first water cooling block 8 by heat-conducting silica gel; the first water cooling block 8 is an aluminum alloy water cooling block and internal circulating water (normal-temperature purified water or ethanol-based heat-conducting liquid); the first water cooling block 8 is connected with a first electromagnetic valve 3, a first self-priming pump 4, a second self-priming pump 6 and a second electromagnetic valve 7 through water pipelines; the first electromagnetic valve 3 and the first self-priming pump 4 are respectively connected with the first water storage device 1 through water pipelines; the second electromagnetic valve 7 and the second self-priming pump 6 are respectively connected with the second water receiver 2 through water pipelines; the first reservoir 1 contains a first one-way outlet valve 27; the second reservoir 2 contains a second one-way vent valve 28; the air pump 5 is respectively connected with the first water storage device 1 and the second water storage device 2 through a pipeline and a first oxygen sand head 30 and a second oxygen sand head 31; the upper surface of the second semiconductor chilling plate 15 generates cooling energy; the upper surface of the second semiconductor refrigeration piece 15 is connected with a second polymer refrigeration storage 25, and the second polymer refrigeration storage 25 is connected with a second refrigeration conduction piece 13; the second refrigeration conducting sheet 13 is in contact with the temperature feedback device 12, and the contact part of the second polymer refrigeration storage 25 and the upper surface of the second semiconductor refrigeration sheet 15 is not connected with the second heat insulation layer 14; the lower surface of the second semiconductor refrigerating sheet 15 is bonded and connected with a second water cooling block 16 by heat-conducting silica gel; the second water cooling block 16 is an aluminum alloy water cooling block, and internal circulating water (normal-temperature purified water or ethanol-based heat-conducting liquid) is arranged in the second water cooling block 16 and is connected with the first electromagnetic valve 3, the first self-priming pump 4, the second self-priming pump 6 and the second electromagnetic valve 7 through water pipelines; the first electromagnetic valve 3 and the first self-priming pump 4 are respectively connected with the first water storage device 1 through water pipelines; the second electromagnetic valve 7 and the second self-priming pump 6 are respectively connected with the second water receiver 2 through water pipelines; the first reservoir 1 contains a first one-way outlet valve 27; the second reservoir 2 contains a second one-way vent valve 28; the first water reservoir 1 and the second water reservoir 2 contain circulating water (normal temperature purified water or ethanol-based heat transfer fluid).

The temperature intelligent control and temperature display module 17 and the time cycle on-off module 18 can be used (used) temperature intelligent control and temperature display modules and time cycle on-off modules for various series of refrigerators. Here, the temperature intelligent control and temperature display 17 is: temperature controller manufactured by Jiangsu river electronics technology Limited company, model: w1209. The time cycle on-off module 18 adopts electronic technology company of Shenzhen aeolian, a time controller, a model: JK11S.

The utility model also provides an air conditioning suit. Fig. 2 is a schematic diagram of the front structure of the air conditioning suit of the present invention. In the figure, 21 is a temperature intelligent control and display part. Fig. 3 is a schematic diagram of the back structure of the air conditioning suit of the present invention. In the figure, 20 is a main unit and a battery pack backpack. Fig. 4 is a schematic diagram of the unfolding structure of the air conditioning suit (inside) of the present invention. In the figure, 22 is a back internal refrigeration and energy storage circulation assembly, 23 is a chest internal refrigeration and energy storage circulation assembly, and 24 is a waterway circulation pipe, a power transmission circuit and a surface heat insulation layer thereof. As shown in fig. 2, 3 and 4, the air conditioning suit is: the wearable device with the semiconductor refrigeration function is arranged in a clothing jacket, and the intelligent temperature control and display component (21) is arranged outside the chest of the clothing jacket; the chest refrigeration and energy storage circulation assembly 23 is arranged in the chest of the coat; the back internal refrigeration and energy storage cycle assembly 22 is mounted inside the back of the garment coat; the host and battery pack backpack 20 is mounted on the outside of the back of the garment coat; the water path circulation pipe, the power transmission circuit and the surface heat insulation layer 24 thereof are arranged in the garment upper garment, between the chest internal refrigeration and energy storage circulation assembly 23 and the back internal refrigeration and energy storage circulation assembly 22.

The utility model discloses application method: turning on an intelligent temperature control and display module (CPU) 17; 12V voltage and 6AH current provided by the lithium battery pack 19 pass through the time cycle on-off module (IC) 18 to simultaneously supply power to the semiconductor refrigerating sheet 9, the semiconductor refrigerating sheet 15, the air pump 5, the self-sucking pump 4 and the electromagnetic valve (normally open type) 7, so that the refrigerating action of the semiconductor refrigerating sheet 9 and the semiconductor refrigerating sheet 15 is started, cold energy is generated, heat energy in the opposite direction is generated, and the cold energy is uniformly conducted through the copper sheets 11 and 13 bonded with the refrigerating sheet 9 and the refrigerating sheet 15, so that the cold energy is uniformly supplied to the periphery of the body in the clothes to generate a cooling effect. Because of the characteristic of rapid refrigeration of the semiconductor refrigeration piece, redundant refrigeration energy is stored through the ice crystal high-molecular refrigeration houses 25 and 26 bonded on the back of the red copper when the human body is supplied with cold, when the main machine works and refrigerates to reach the interval temperature and the semiconductor refrigeration piece stops working and running, the stored redundant refrigeration energy is continuously provided for the human body for refrigeration, the energy is used alternately, the electric energy of the battery pack is saved, and the environment-friendly effect is achieved. When the semiconductor refrigerating sheets 9 and 15 are in refrigerating operation, the generated heat energy is conducted to the water storage device through the water-based heat-conducting liquid in the aluminum alloy water-cooling blocks 8 and 16 bonded with the semiconductor refrigerating sheets by the heat-conducting silica gel, at the moment, the electromagnetic valve 7 is closed, the self-sucking pump 4 works, and the air pump 5 works. Therefore, the heat in the water-based heat-conducting liquid is fully fused with the water-based liquid through the bubbles generated by the sand oxygen head 30 by the normal-temperature gas pumped outside the clothes by the air pump 5, so that the heat is efficiently exchanged and discharged to the air through the one-way exhaust valve 27, and efficient heat discharge is realized. When the time on-off module sets the operating time to reach 10 minutes, can self-closing solenoid valve 3, make the water base liquid in the water receiver 2 participate in, the heat transfer cycle principle is the same, and the water base liquid in the water receiver 1 withdraws from the heat cycle, but the air pump 5 in the water receiver 1 continues to the water base liquid cooling with the normal atmospheric temperature gas of supply, the water base liquid of two water receivers 1 and 2 uses in turn like this, the heat is taken away in the high-efficient heat transfer cycle of one in use, the rest cooling in another group, accomplish the high-efficient operation of heat transfer mode scientific configuration, it can produce the same effect to make two single normally open solenoid valves in the whole refrigeration effect reaches best operation notes system can be replaced with a three-way solenoid valve of 12v200 ma.

The utility model discloses can adopt embodiments such as 6V semiconductor refrigeration piece and 24V semiconductor refrigeration piece and 36V refrigeration piece, only need be equipped with different lithium battery charging group, demonstrate the little big difference in refrigerating output. The weight and the refrigeration efficiency are comprehensively considered, and the matching refrigeration effect and the device weight of the 12V semiconductor refrigeration piece and the 12V 6Ah lithium battery pack can be better.

In a word, the utility model discloses a semiconductor refrigeration piece, refrigeration conduction piece, water receiver, lithium cell group etc. technique can obtain lightly, good-looking, the high semiconductor refrigeration of refrigeration effect and can exchange refrigeration system and its clothing (air conditioner clothes) with two in actual life and work, has positive market prospect.

Claims (8)

1. The wearable device for semiconductor refrigeration is characterized in that: a temperature intelligent control and display part (21) which comprises an intelligent temperature control and display module (17); the front chest refrigeration and energy storage circulation assembly (23) comprises a first water cooling block (8), a first semiconductor refrigeration sheet (9), a first heat insulation layer (10) and a first refrigeration conduction sheet (11); the water path circulating pipe, the power transmission circuit and the surface heat insulation layer (24) thereof comprise a water pipe, an electric wire and the surface heat insulation layer thereof; the back internal refrigeration and energy storage circulating assembly (22) comprises a temperature feedback device (12), a second refrigeration conducting sheet (13), a second heat insulation layer (14), a second semiconductor refrigeration sheet (15) and a second water cooling block (16); the main machine and battery pack backpack (20) comprises a first water storage device (1), a second water storage device (2), a first electromagnetic valve (3), a first self-sucking pump (4), an air pump (5), a second self-sucking pump (6), a second electromagnetic valve (7), a time cycle on-off module (18), a lithium battery pack (19), a first one-way exhaust valve (27), a second one-way exhaust valve (28), a first sand oxygen head (30) and a second sand oxygen head (31);

the lithium battery pack (19) is connected with the time cycle on-off module (18);

the time cycle on-off module (18) is connected with the intelligent temperature control and display module (17), the first semiconductor refrigerating sheet (9), the first water cooling block (8), the second semiconductor refrigerating sheet (15), the second water cooling block (16), the first electromagnetic valve (3), the first self-priming pump (4), the air pump (5), the second self-priming pump (6) and the second electromagnetic valve (7);

the intelligent temperature control and display module (17) is connected with the temperature feedback device (12);

the upper surface of the first semiconductor refrigeration sheet (9) generates cold energy; the upper surface of the first semiconductor refrigeration sheet (9) is connected with a first refrigeration conduction sheet (11); the lower surface of the first semiconductor refrigeration sheet (9) is connected with a first water cooling block (8);

the first water cooling block (8) is an aluminum alloy water cooling block and internal circulating water;

the first water cooling block (8) is connected with the first electromagnetic valve (3), the first self-priming pump (4), the second self-priming pump (6) and the second electromagnetic valve (7) through water pipelines;

the first electromagnetic valve (3) and the first self-sucking pump (4) are respectively connected with the first water receiver (1) through water pipelines;

the second electromagnetic valve (7) and the second self-priming pump (6) are respectively connected with the second water receiver (2) through water pipelines;

the first reservoir (1) contains a first one-way venting valve (27);

the second reservoir (2) contains a second one-way venting valve (28);

the air pump (5) is respectively connected with the first water storage device (1) and the second water storage device (2) through a pipeline and the first sand oxygen head (30) and the second sand oxygen head (31);

the upper surface of the second semiconductor refrigerating sheet (15) generates cold energy; a second refrigeration conducting sheet (13) is arranged on the upper surface of the second semiconductor refrigeration sheet (15); the second refrigeration conducting piece (13) is in contact with the temperature feedback device (12);

the lower surface of the second semiconductor refrigerating sheet (15) is connected with a second water cooling block (16); the second water cooling block (16) is an aluminum alloy water cooling block and internal circulating water;

the second water cooling block (16) is connected with the first electromagnetic valve (3), the first self-priming pump (4), the second self-priming pump (6) and the second electromagnetic valve (7) through water pipelines;

the first water storage tank (1) and the second water storage tank (2) contain circulating water.

2. The wearable device for semiconductor refrigeration according to claim 1, wherein the chest refrigeration and energy storage cycle assembly (23) further comprises a first polymer refrigeration storage room (26), the upper surface of the first semiconductor refrigeration sheet (9) is connected to the first polymer refrigeration storage room (26), the first polymer refrigeration storage room (26) is further connected to the first refrigeration conductive sheet (11), and the first polymer refrigeration storage room (26) is connected to the first thermal insulation layer (10); the back internal refrigeration and energy storage circulation assembly (22) further comprises a second high polymer refrigeration storage house (25), the upper surface of the second semiconductor refrigeration sheet (15) is connected with the second high polymer refrigeration storage house (25), and the second high polymer refrigeration storage house (25) is further connected with a second refrigeration conduction sheet (13); the second macromolecule refrigeration storage (25) is connected with the second heat insulation layer (14).

3. A semiconductor-cooled wearable device according to claim 2, characterized in that the first polymer cold store (26) and the second polymer cold store (25) are ice crystals.

4. A semiconductor-refrigerated wearable device according to claim 1 characterized in that the host and battery pack backpack (20) each further comprises a first sand-oxygen head (30), a second sand-oxygen head (31); the air pump (5) is respectively connected with the first water storage device (1) and the second water storage device (2) through a pipeline and the first sand oxygen head (30) and the second sand oxygen head (31).

5. A wearable semiconductor refrigeration device according to claim 1, characterized in that the first semiconductor refrigeration piece (9) and the second semiconductor refrigeration piece (15) are 12703 semiconductor refrigeration pieces respectively.

6. The wearable device with semiconductor refrigeration function according to claim 1, wherein the first refrigeration conducting piece (11) and the second refrigeration conducting piece (13) are made of red copper.

7. The wearable device with semiconductor refrigeration according to claim 1, characterized in that the first and second thermal insulation layers (10, 14) are aerogel thermal insulation layers with a thermal conductivity of 0.018W/(m-K) at normal temperature and 0.009W/(m-K) at low temperature.

8. An air conditioning suit characterized in that a semiconductor-cooled wearable device as claimed in any one of claims 1 to 7 is installed in the suit top,

the temperature intelligent control and display component (21) is arranged outside the chest of the coat;

the chest refrigeration and energy storage circulation assembly (23) is arranged in the chest of the coat;

the back internal refrigeration and energy storage cycle assembly (22) is arranged inside the back of the coat;

the main machine and the battery pack backpack (20) are arranged outside the back of the coat;

the water path circulating pipe, the power transmission circuit and the surface heat insulation layer (24) of the water path circulating pipe and the power transmission circuit are arranged in the garment upper garment, between the chest internal refrigeration and energy storage circulation assembly (23) and between the back internal refrigeration and energy storage circulation assembly (22).

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