AU2020100694A4

AU2020100694A4 - An intelligent neckband fever cooling apparatus

Info

Publication number: AU2020100694A4
Application number: AU2020100694A
Authority: AU
Inventors: Honglin Chen; Liangyuan Chen; Mingqi Jiang; Peiyu Liao; Haicheng Lin; Mingyao Liu; Siyi Ren; Chen XUE; Yaru Yang; Yaoyang ZHANG; Yao Zhu; Zihao Zhu
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-04
Filing date: 2020-05-04
Publication date: 2020-06-11
Anticipated expiration: 2028-05-04

Abstract

Abstract The utility model discloses an intelligent neckband fever cooling apparatus, comprising a host case, a cooling water storing capsule and a temperature meter, wherein the host case is deployed with a controller, a water pump, cooling tank, cooling components and batteries; and the cooling components are composed of cooling blocks connected in order and attached to the wall of the cooling tank, thermoelectric coolers and cooling fans. Ventilation holes are perforated in host case's wall where the cooling fans are located. There is a smooth water channel inside the water storing capsule, with its intake end connected to the outlet of water pump through its intake pipe, while its discharge end, as well as the inlet of the water pump, is connected to the cooling tank through the discharge pipe and the connection pipe respectively. Thermoelectric coolers and cooling fans are linked to the host batteries. The utility model features easy temperature measurement and superior cooling effect. The neckband water storing capsule, with simple structure and comfort wearing, can work for a long time without falling off. Fig. 1 Fig. 2

Description

An intelligent neckband fever cooling apparatus

Technical Field

[0001] The utility model relates to the technical field of medical apparatus, in particular to an intelligent neckband fever cooling apparatus for children.

Background

[0002] Fever, commonly seen in diseases, can directly do harm to human brain cells in severe cases, making patients suffer from mental retardation. For now, there are basically two approaches to bringing down the fever of kids, one is medication by taking medicine or injection, with adverse drug side effects on their growth; and the other is physical therapy by cooling relief gel patch or physical cooling apparatus, with poor relief effect, easy access to skin allergy, and uncomfortable wearing experience due to sticky materials. Kids tend to roll over at night and get rid of fever cooling apparatus (while their temperatures are usually higher at night). Most cooling devices are not intelligent enough to set parents free from realtime observation. Therefore, negligence occurs unexpectedly when they are physically and mentally tired.

Summary

[0003] To solve the problems aforesaid, the utility model aims to introduce a handy fever cooling apparatus that is well designed for children with brilliant relief effects.

[0004] The technical solution adopted by the utility model to achieve the above purpose is as follows:

[0005] An intelligent neckband fever cooling apparatus, comprising a host case, a cooling water storing capsule and a temperature meter. The host case is deployed with a controller, a water pump, a cooling tank, cooling components and batteries. Cooling components are composed of cooling blocks connected in order and attached to the wall of cooling tank, thermoelectric coolers and cooling fans. Ventilation holes are perforated in host case's wall where the cooling fans are located. There is a smooth water channel inside the water storing capsule, with its intake end connected to the outlet of water pump through its intake pipe,

2020100694 04 May 2020 while its discharge end, as well as the inlet of the water pump, is connected to the cooling tank through the discharge pipe and the connection pipe respectively. Thermoelectric coolers and cooling fans are linked to the host batteries, while the temperature meter, thermoelectric coolers, cooling fans and host batteries are connected to the controller.

[0006] Further, the cooling tank is divided into a relief chamber and a refrigeration chamber through a horizontal separator; the discharge pipe is connected to the relief chamber, while the connection pipe is connected to the refrigeration chamber. Both discharge pipe and connection pipe are assembled on the same side of the host case, and the horizontal separator is punched with chamber holes on the side away from the discharge pipe for the connection between relief and refrigeration chambers.

[0007] Multiple sets of cooling components and host batteries are connected correspondingly. For better refrigeration effect, all host batteries are set above the relief chamber. Storage chambers are arranged beneath the refrigeration chamber by separators, with all cooling components settled inside. Each set of thermoelectric coolers is closed to the walls of refrigeration chamber.

[0008] A primary temperature sensor is built in the refrigeration chamber, connected to a primary temperature display outside. Both are connected to the controller.

[0009] Further, the circular temperature meter is designed for kids, comprising an unsealed elastic circle, with a measurement battery, a secondary sensor measuring axillary temperature, and a Bluetooth modular transmitting data to the controller built in. The Bluetooth modular, the measurement battery and the secondary sensor are connected clockwise.

[0010] For real-time data on body temperature, the external wall of the host case is installed with the secondary temperature display in connection with the controller.

[0011] Further, the host batteries are chargeable, and a charging interface, a battery light and a charge indicator light are assembled outside the wall. The latter two lights are connected to the host batteries.

[0012] Further, both ends of the water storing capsule are connected by a buckle.

2020100694 04 May 2020

[0013] Further, inside the host case, there is a wireless communication modular connected to the controller to transmit temperature data to mobile App in real time.

[0014] Further, for more comfortable wearing experience, the water storing capsule is made of silica gel.

[0015] The beneficial effects of the utility model are as follows: an intelligent neckband fever cooling apparatus for children is provided, comprising a water storing capsule for easy and normal use at night without falling. Temperature can be controlled intelligently to free parents from real-time observation and manifest data visually. Meanwhile, data are transmitted to parents via mobile App, etc. It is well designed, featuring simple structure, easy access and long-term running. Costs of production and utilization are relatively low, but the relief effect and the life are marvelous.

Brief Description of Drawings

[0016] Fig. 1 is a schematic structural diagram of the utility model.

[0017] Fig. 2 is a schematic structural diagram of the host case.

[0018] Fig. 3 is a schematic structural diagram of the host case from another point of view.

[0019] Fig. 4 is the internal structural diagram of the host case.

[0020] Fig. 5 is the internal structural diagram of the circular temperature meter.

[0021] Fig. 6 is the working conditions of the utility model.

[0022] Description of major component symbols: 1. host case; 10. ventilation hole; 11. controller; 12. waterpump; 120. connection pipe; 13. cooling tank; 130. horizontal separator; 131. relief chamber; 132. refrigeration chamber; 133. chamber hole; 134. storage chamber; 135. primary temperature sensor; 14. cooling components; 141. cooling block; 142.

thermoelectric cooler; 143. cooling fan; 15. host battery; 16. wireless communication modular; 17. primary temperature display; 18. secondary temperature display; 19. charging interface; 110. battery level indicator; 111. battery charge indicator; 112. power switch; 2.

2020100694 04 May 2020 water storing capsule; 20. buckle; 21. intake pipe; 22. discharge pipe; 3. circular temperature meter; 31. unsealed elastic circle; 32. temperature meter battery; 33. secondary temperature sensor; 34. Bluetooth modular.

Description of Embodiments

[0023] The utility model will be further illustrated with attached drawings and detailed description of the embodiments.

[0024] As shown in Fig. 1-6, an intelligent neckband fever cooling apparatus for children is composed of the host case 1, the cooling water storing capsule 2 and a circular temperature meter 3. The host case 1 is deployed with the controller 11, the water pump 12, cooling tank 13, cooling components 14, host batteries 15 and the wireless communication modular 16. Host batteries 15 are chargeable, and a charging interface 19, a battery level indicator 110 and a battery charge indicator 111 are assembled outside the wall of host case 1. The latter two lights are connected to the host batteries 15.

[0025] The cooling tank 13 is divided into a relief chamber 131 and a refrigeration chamber 132 through a horizontal separator 130. There is a smooth water channel (not shown in the figure) inside the water storing capsule 2 made of silica gel, with both ends connected by a buckle 20. Its intake end connected to the outlet of water pump 12 through its intake pipe 21, while its discharge end, as well as the inlet of the water pump 12, is connected to the relief chamber 131 and the refrigeration chamber 132 through the discharge pipe 22 and the connection pipe 120 respectively. Both discharge pipe 22 and connection pipe 120 are assembled on the same side of the host case 1. The horizontal separator 130 is punched with chamber holes 133 on the side away from the discharge pipe 22 for the connection between relief chamber 131 and refrigeration chamber 132.

[0026] Cooling components 14 are composed of cooling blocks 141 connected in order and attached to the wall of refrigeration chamber 132, thermoelectric coolers 142 and cooling fans 143. Ventilation holes 10 are perforated in host case's 1 wall where the cooling fans 142 are located. Thermoelectric coolers 142 and cooling fans 143 are linked to the host batteries 15. Multiple sets of cooling components 14 and host batteries 15 are connected correspondingly. All host batteries 15 are set above the relief chamber 131. Storage chambers 134 are arranged

2020100694 04 May 2020 beneath the refrigeration chamber 132 by separators and cooling components 14 are built in them. A primary temperature sensor 135 is built in the refrigeration chamber 132, connected to a primary temperature display 17 outside the host case 1.

[0027] The circular temperature meter 3 is composed of an unsealed elastic circle 31, with a measurement battery 32, a secondary sensor 33 measuring axillary temperature, and a Bluetooth modular 34 transmitting data to the controller 11 built in. The Bluetooth modular 34, the measurement battery 32 and the secondary sensor 33 are connected clockwise. The external wall of the host case 1 is installed with the secondary temperature display 18 to show the data read by the secondary temperature sensor 33.

[0028] Wireless communication modular 16, secondary temperature display 18, Bluetooth modular 34, primary temperature sensor 135, primary temperature display 17, thermoelectric coolers 142, cooling fans 143 and host batteries 15 are connected to the controller 11.

[0029] The working principle of the utility model is as follows: enable the kid with a fever to wear the neckband water storing capsule 2, with its both ends connected by a buckle 20. Clamp the circular temperature meter 3 on the kid's arm and keep the secondary temperature sensor 33 under the armpit. Turn on the power switch 112 of the host case 1 to enable the thermoelectric cooler 142 and cooling fan 143 to work, thus cooling down the water in the refrigeration chamber 132 via cooling blocks 141. The operating frequency and duration of three independent cooling components 14 are controlled by the controller 11. Both frequency and duration depend on the temperature measured by the circular temperature meter 3. The lower the temperature, the higher the frequency and the longer the duration, and vice versa. In case that the water temperature in the refrigeration chamber 132 is low enough, say 15°C, the controller 11 will send a command to the water pump 12 to pull the water out and pump into the water storing capsule 2 to form a loop. The water will flow into the relief chamber 131 and then into the refrigeration chamber 132 through the holes 133 on the separator 130.

[0030] The temperature data measured by the secondary sensor 33 will be transmitted to the controller 11 by the Bluetooth modular 34 in the circular temperature meter 3, and then be revealed on the secondary display 18 outside the host case 1. Tied in the apparatus and the mobile App, the wireless communication modular 16 will send data to the App, so that parents will be reminded and warned subject to temperature changes.

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[0031] The above are the preferred embodiments of the utility model. Any change occurs to the forms and details not deviating from the spirit and scope of the utility model as defined in the attached claim, as those skilled in the field should know, shall fall into the scope of the utility model.

Claims

CLAIMS:

1. An intelligent neckband fever cooling apparatus for children, comprising a host case, a neckband cooling water storing capsule and a temperature meter, wherein the host case is deployed with a controller, a water pump, a cooling tank, cooling components and batteries, and the cooling components are composed of cooling blocks connected in order and attached to the wall of cooling tank, thermoelectric coolers and cooling fans. Ventilation holes are perforated in host case's wall where the cooling fans are located. There is a smooth water channel inside the water storing capsule, with its intake end connected to the outlet of water pump through its intake pipe, while its discharge end, as well as the inlet of the water pump, is connected to the cooling tank through the discharge pipe and the connection pipe respectively. Thermoelectric coolers and cooling fans are linked to the host batteries, while the temperature meter, thermoelectric coolers, cooling fans and host batteries are connected to the controller.
2. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein the cooling tank is divided into a relief chamber and a refrigeration chamber through a horizontal separator; the discharge tube is connected to the relief chamber, while the connection pipe is connected to the refrigeration chamber. Both discharge pipe and connection pipe are assembled on the same side of the host case, and the horizontal separator is punched with chamber holes on the side away from the discharge pipe for the connection between relief and refrigeration chambers.
3. An intelligent neckband fever cooling apparatus for children according to claim 2, wherein multiple sets of cooling components and host batteries are connected correspondingly. All host batteries are set above the relief chamber, while storage chambers are arranged beneath the refrigeration chamber by separators, with all cooling components settled inside. Each set of thermoelectric coolers is closed to the walls of refrigeration chamber.
4. An intelligent neckband fever cooling apparatus for children according to claim 2, wherein a primary temperature sensor is built in the refrigeration chamber, connected to a primary temperature display outside. Both are connected to the controller.

2020100694 04 May 2020
5. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein the circular temperature meter is designed for kids, comprising an unsealed elastic circle, with a measurement battery, a secondary sensor measuring axillary temperature, and a Bluetooth modular transmitting data to the controller built in. The Bluetooth modular, the measurement battery and the secondary sensor are connected clockwise.
6. An intelligent neckband fever cooling apparatus for children according to claim 5, wherein the external wall of the host case is installed with the secondary temperature display in connection with the controller.
7. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein the host batteries are chargeable, and a charging interface, a battery level indicator and a battery charge indicator are assembled outside the wall. The latter two lights are connected to the host batteries.
8. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein both ends of the water storing capsule are connected by a buckle.
9. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein inside the host case, there is a wireless communication modular connected to the controller to transmit temperature data to mobile App in real time.
10. An intelligent neckband fever cooling apparatus for children according to claim 1, wherein the water storing capsule is made of silica gel.