TWM495881U - Solar temperature-sensing lifebuoy - Google Patents

Description

Solar thermal lifebuoy

The present invention relates to a solar temperature-sensing lifebuoy, in particular to a temperature sensor and a micro-temperature controller, and the micro-temperature controller can sense the temperature of the lifebuoy surface according to the temperature sensor; Overheating automatically adjusts the speed of the micro fan to regulate the temperature to achieve a new lifebuoy.

The traditional lifebuoy cannot be automatically temperature-controlled in accordance with the change of the temperature of the lifebuoy surface, so the user often feels too cold or overheated, which is a drawback.

In view of the above, there is a need for a solar temperature-sensing lifebuoy having a temperature sensor and a micro-temperature controller, and the micro-temperature controller can be overheated when the lifebuoy surface temperature is sensed according to the temperature of the lifebuoy surface sensed by the temperature sensor. The speed of the micro fan can be automatically adjusted to maintain the temperature of the lifebuoy surface within a preset range to improve the shortcomings of the conventional temperature difference.

The purpose of the present invention is to provide a solar temperature-sensing lifebuoy, which can automatically adjust the rotation speed of the micro-fan according to the temperature of the lifebuoy surface to achieve the effect of temperature regulation.

In order to achieve the above purpose, the solar heat-sensing lifebuoy of the present invention has at least: a temperature sensor for measuring the surface temperature of the lifebuoy; and a micro-temperature controller coupled to the temperature sensor, which has a timer; an input and marking device coupled to the micro thermostat, The utility model can be used for setting and indicating the starting temperature and the basic rotating speed of the micro fan described later; a micro solar panel is coupled to the micro thermostat, and can receive the driving of the micro thermostat to supply electric energy to the micro fan described later; The micro fan is coupled to the micro temperature controller and can be driven to rotate by the micro temperature controller, and the micro temperature controller can control the micro fan according to the temperature of the lifebuoy surface detected by the temperature sensor. The rotation speed is such that the lifebuoy surface temperature is controlled within a preset temperature range.

In order to provide a further understanding of the structure, features, and objects of the present invention, the detailed description of the drawings and the preferred embodiments are set forth below.

10‧‧‧Traditional lifebuoy

20‧‧‧Lifebuoy surface temperature controller

30‧‧‧Printed circuit board

40‧‧‧temperature sensor

50‧‧‧Micro-temperature controller

60‧‧‧Input and marking devices

70‧‧‧Micro solar panels

80‧‧‧Micro Fan

T‧‧‧Lifebuoy surface temperature

R‧‧‧ Basic speed of micro fan 80

Figure 1 is a combination diagram.

FIG. 2 is a schematic diagram showing a block diagram of a lifebuoy surface temperature controller 20 according to a preferred embodiment of the present invention.

FIG. 3 is a schematic diagram showing the operation of the lifebuoy surface temperature controller 20.

Referring to Fig. 1, the creation is a combination of a conventional lifebuoy 10 and a lifebuoy surface temperature controller 20. The traditional lifebuoy 10 of the present invention is a well-known technique and is not the focus of the present case, so it is not described here.

Referring to FIG. 2 and FIG. 3 together, FIG. 2 is a block diagram showing a lifebuoy surface temperature controller 20 according to a preferred embodiment of the present invention, and FIG. 3 is a diagram showing the operation flow of the lifebuoy surface temperature controller 20. Figure.

As shown in FIG. 2, the created lifebuoy surface temperature controller 20 includes at least: a printed circuit board 30; a temperature sensor 40; a micro temperature controller 50; an input and indicator A device 60; a miniature solar panel 70; and a microfan 80 are combined.

The printed circuit board 30 is used to carry the temperature sensor 40, the micro temperature controller 50, the input and display device 60, the micro solar panel 70, and the micro fan 80, which are conventional technologies and are not the focus of the present application. I will not go into details here.

The temperature sensor 40 is placed on the printed circuit board 30 and can be used to measure the lifebuoy surface temperature, such as, but not limited to, a temperature sensor.

The micro-temperature controller 50 is disposed on the printed circuit board 30 and coupled to the temperature sensor 40, and has a timer and a program (all not shown). The setting value of the timer is, for example but not limited to, 3 minutes, and the program can perform the control of the rotation speed of the micro fan 80 according to the temperature value sensed by the temperature sensor 40.

The input and display device 60 is disposed on the printed circuit board 30 and coupled to the micro temperature controller 50 for setting and indicating data such as the starting temperature and the basic rotational speed of the micro fan 80. The input portion of the input and display device 60 is, for example but not limited to, a keyboard or a plurality of buttons, and further includes a + button, a - button, and a confirmation button. In this embodiment, the button is composed of a plurality of buttons. For example, the description is not limited thereto; for example, the indication portion of the input and marking device 60 is, for example but not limited to, liquid crystal; and the input and marking device 60 is a touch input and marking device.

The micro solar panel 70 is disposed on the printed circuit board 30 and coupled to the micro thermostat 50 to convert the energy contained in the sunlight into electrical energy through photoelectric conversion and to accept the micro thermostat 50. The electric power is supplied to the micro fan 80 by driving.

The micro fan 80 is disposed on the printed circuit board 30 and coupled to the micro solar panel 70 to receive the electrical energy of the micro solar panel 70 to emit a desired rotational speed.

As shown in FIG. 3, when the lifebuoy surface temperature controller 20 of the present invention is in operation, the lifebuoy surface temperature is set to 27 ° C and the basic rotation speed R of the micro fan 80 via the input and marking device 60; then the micro fan 80 is activated. Inductive lifebuoy surface temperature, when the lifebuoy surface temperature> 28 °C, the microfan 80 speed is automatically multiplied by 1.5 times and the lifebuoy surface temperature is continuously induced, otherwise the timer is started and the micro fan 80 speed is reduced to 0.9R; Within a minute, the temperature of the lifebuoy surface sensed by the temperature sensor 40 continues to decrease the speed of the micro fan 80 to 0.9R (ie, 0.81R), so that the temperature of the lifebuoy surface is not rapidly reduced, otherwise the micro thermostat 50 judge whether the temperature difference of the lifebuoy surface within 3 minutes is <1 ° C, if otherwise, the timer is reset to zero, if so, the rotation speed R of the micro fan 80 is set to the minimum rotation speed; the temperature sensor 40 senses whether the temperature of the lifebuoy surface rises 2 °C, if it continues to sense, if it is, multiply the speed of the micro fan 80 by 1.2 times, so that the micro fan 80 rotates quickly to reduce the temperature of the lifebuoy surface, and reset the timer to zero, and return to within 3 minutes. The temperature of the lifebuoy surface induced by the temperature sensor 40 continues to decrease, and the rotation speed of the micro fan 80 is further reduced to 0.9R (that is, the original 0.81R).

As described above, the lifebuoy surface temperature controller 20 of the present invention can set the lifebuoy surface temperature and the basic rotation speed R of the micro fan 80 at the beginning, and the micro thermostat 50 lowers the micro fan 80 when the temperature drops rapidly. The rotation speed is such that the temperature slowly rises. When the temperature rises above the preset temperature, the micro thermostat 50 increases the rotation speed of the micro fan 80 to gradually lower the temperature. Therefore, the lifebuoy surface temperature controller of the present invention can automatically perform the control of the micro fan speed according to the temperature of the lifebuoy surface, in addition to increasing the user's comfort, and also reducing the energy consumption, which is indeed more advanced than the conventional lifebuoy. The disclosure of the present invention is a preferred embodiment. Any change or modification of the present invention originating from the technical idea of the present invention and being easily inferred by those skilled in the art will not deviate from the scope of patent rights of the present invention.

In summary, the case, regardless of its purpose, means and efficacy, is marking its technical characteristics that are different from the conventional knowledge, and its first creation is practical, and it is also in compliance with the new patent requirements. Pray for the patents at an early date.

30‧‧‧Printed circuit board

40‧‧‧temperature sensor

50‧‧‧Micro-temperature controller

60‧‧‧Input and marking devices

70‧‧‧Micro solar panels

80‧‧‧Micro Fan

Claims (8)

A solar temperature-sensing lifebuoy comprising a lifebuoy surface temperature controller and a lifebuoy, and the lifebuoy surface temperature controller is contained in the lifebuoy, the lifebuoy surface temperature controller having at least: a temperature sensor for measuring the lifebuoy a micro temperature controller coupled to the temperature sensor and having a timer; an input and indicator device coupled to the micro thermostat for setting a starting temperature and a micro fan described later The basic rotating speed and the data indicating the starting temperature and the basic rotating speed of the micro fan; a miniature solar panel coupled to the micro thermostat, capable of receiving the driving of the micro thermostat to supply electric energy to the micro fan described later; And a micro-fan coupled to the micro solar panel to receive the electric power required for the rotation of the micro solar panel; the micro thermostat can be controlled according to the temperature of the lifebuoy surface detected by the temperature sensor The speed of the micro fan is such that the lifebuoy surface temperature is controlled within a preset temperature range. The solar temperature-sensing lifebuoy according to claim 1, further comprising a printed circuit board for carrying the temperature sensor, the micro-temperature controller, the input and marking device, the micro solar panel and the micro fan. The solar thermal lifebuoy according to claim 1, wherein the micro thermostat further has a program to perform the control of the micro fan speed. The solar temperature-sensing lifebuoy according to claim 1, wherein the input and marking device can be a keyboard or a plurality of buttons and a liquid crystal marking device. The solar thermal lifebuoy according to claim 4, wherein the plurality of buttons and the liquid crystal marking device are combined to form a touch input and marking device. The solar thermal lifebuoy according to claim 1, wherein the timer is set to 3 minutes. The solar thermal lifebuoy according to claim 1, wherein the micro fan has a rotational speed ranging from 0.9 to 1.2 basic rotational speed. The solar temperature-sensitive lifebuoy according to claim 1, wherein the starting temperature is 27 °C.