INTELLIGENT BELT THAT AUTOMATICALLY MONITORS WAISTLINE AND OF WHICH THE LENGTH IS ADJUSTED BY AN ELECTROMAGNETIC ARRAY

Abstract

The intelligent belt of the invention that automatically monitors waistline and of which the length is adjusted by the electromagnetic array, includes the buckle and the belt body. The buckle includes the waistline-measuring device, the length-adjusting device and the belt-body-fastening device. The measuring device, the length-adjusting device, and the belt-body-fastening device all include a hollow housing with a cuboid shape. The housings are connected in turn by hinges. The waistline-measuring device includes a roller, a rotary encoder, and a counter. The length-adjusting device includes a micro controller, a gyroscope, a wireless transceiver, an accelerometer, a pressure sensor, a platen, a magnet and an electromagnetic array that are positioned in the inner cavity. One end of the belt body is fixedly connected to the belt-body-fastening device. The other end of the belt body is provided with a slot and an adjusting buckle. The intelligent belt has reasonable and structure, easy to use, safe, reliable, and high degree of intelligence, which effectively solve the problem regarding common belts being unable to automatically adjust the length.

Claims

1. An intelligent belt that automatically monitors waistline and of which is adjusted by an electromagnetic array, comprising: a buckle 1 and a belt body 2, wherein the buckle 1 includes a waistline-measuring device 11, a length-adjusting device 12, and a belt-body-fastening device 13; the waistline-measuring device 11, the length-adjusting device 12, and the belt-body-fastening device 13 all include a hollow housing with a cuboid shape; the housings are connected in turn by hinges 112; the waistline-measuring device 11, the length-adjusting device 12, and the belt-body-fastening device 13 are provided with a first groove 111, a second groove 121, and a third groove 131 that the belt body passes through, respectively, wherein the waistline-measuring device 11 includes a roller 13, a rotary encoder 114, and a counter 115; the roller 113 is positioned in the inner cavity of the waistline-measuring device 11; a portion of the roller 113 extends into the first groove 111 and contacts with the belt body 2; the rotary encoder 114 electrically connects with the roller 113; the rotary encoder 114 electrically connects with the counter 115, wherein the length-adjusting device 12 includes a micro controller 123, a gyroscope 124, a wireless transceiver 125, an accelerometer 126, and a battery 127 that are positioned in the inner cavity; a pressure sensor 116 positioned on the hinge 112; a platen 128, a magnet 129, and a first electromagnet 120 provided on the inner wall of the cavity of the length-adjusting device 12; and an electromagnetic array 122 disposed on the sidewalls of the second groove 121; the platen 128 is hinged to the housing; the magnet 129 and the first electromagnet 120 are respectively arranged in the housings on both sides of the hinge point of the platen 128; the platen 128 extends into the second groove 121 and contacts with the belt body 2; the electromagnetic array 122 is arranged by a plurality of second electromagnets 1221 in the direction of the movement of the belt body 2, and wherein the belt-body-fastening device 13 is provided with an indentation 1321; one end of the belt body 2 is inserted into the indentation 1321 and fixedly connected by an L-shaped gusset plate 132 hinged to the belt-body-fastening device 13; the other end of the belt body2 is provided with a slot 21 and an adjusting buckle 22; the adjusting buckle 22 is made of two pieces of C-shaped plates 221; and the adjusting buckle 22 is provided with an iron plate 222 inside the adjusting buckle 22.

2. The intelligent belt of claim 1, wherein the center axis of the roller is disposed perpendicular to the direction of movement of the belt body.

3. The intelligent belt of claim 1, wherein the roller is made of rubber material or is provided with a rubber layer on its surface.

4. The intelligent belt of claim 1, wherein the pressure sensor 116 is a wafer type pressure sensor positioned between a chain plate of the hinge 112 and a shaft.

5. The intelligent belt of claim 1, wherein the micro controller 123 is electrically connected to the gyroscope 124, the wireless transceiver 125, the accelerometer 126, the battery 127, the pressure sensor 116, the counter 115, the electromagnetic array 122, and the first electromagnet 120, respectively.

6. The intelligent belt of claim 1, wherein the platen 128 extends into one end of the second groove 121 and contacts with the slot 21.

7. The intelligent belt of claim 1, wherein the length-adjusting device 12 is provided with a USB interface 1271 with a charging and discharging circuit, and the USB interface 1271 is electrically connected to the battery 127.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] The invention is illustrated by the following figures and embodiments.

[0017] FIG. 1 shows a schematic diagram of whole structure of an intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array in accordance with an example embodiment.

[0018] FIG. 2 shows a schematic diagram of a cross section of the buckle of the intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array.

[0019] FIG. 3 shows a schematic diagram of the hinges of the intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array.

[0020] FIG. 4 shows an enlarged schematic diagram of waistline-measuring device of the intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array.

[0021] FIG. 5 shows a schematic diagram of the belt body of the intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array.

[0022] FIG. 6 shows a schematic diagram of the adjusting buckle of the intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array.

[0023] The reference signs of the figures are as follows: 1: buckle; 11: waistline-measuring device; 111: first groove; 112: hinge; 113: roller; 114: rotatory encoder; 115: counter; 116: pressure sensor; 12: length-adjusting device; 120: first electromagnet; 121: second groove; 122: electromagnetic array; 1221: second electromagnet; 123: micro controller; 124: gyroscope; 125: wireless transceiver; 126: accelerometer; 127: batter; 1271: USB interface; 128: platen; 129: magnet; 13: belt-body-fastening device; 131: third groove; 132: L-shaped gusset plate; 1321: indentation; 2: belt body; 21: slot; 22: adjusting buckle; 221: C-shaped plate; 222: iron plate.

DETAILED DESCRIPTION

[0024] The invention is illustrated in accordance with figures. The figures as simplified diagrams demonstrate the basic structures of the apparatus of embodiments of the invention. Thus, the invention is not limited to the figures.

[0025] The intelligent belt that automatically monitors waistline and of which the length is adjusted by an electromagnetic array in accordance with FIGS. 1-6 includes a buckle 1 and a belt body 2, wherein the buckle 1 includes a waist-measuring device 11, a length-adjusting device 12 and a belt-body-fastening device 13. The waistline-measuring device 11, the length-adjusting device 12, and the belt-body-fastening device 13, all include a hollow housing with a cuboid shape. The housings are connected in turn by hinges 112. The waistline-measuring device 11, the length-adjusting device 12, and the belt-body-fastening device 13 are provided with a first groove 111, a second groove 121, and a third groove 131 that the belt body passes through, respectively.

[0026] The waistline-measuring device 11 includes a roller 113, a rotary encoder 114, and a counter 115. The roller 113 is positioned in the inner cavity of the waistline-measuring device 11. A portion of the roller 113 extends into the first groove 111 and contacts with the belt body 2. The rotary encoder 114 electrically connects with the roller 113. The rotary encoder 114 electrically connects with the counter 115. The movement of belt body 2 drives the rotation of the roller 113. The rotatory encoder 114 and the counter 115 cooperate to detect the length of the belt body 2 that passes through the first groove 111.

[0027] The belt-body-fastening device 13 is provided with an indentation 1321. One end of the belt body 2 is inserted into the indentation 1321 and fixedly connected by an L-shaped gusset plate 132 hinged to the belt-body-fastening device 13. The other end of the belt body2 is provided with a slot 21 and an adjusting buckle 22. The adjusting buckle 22 is made of two pieces of C-shaped plates 221. The adjusting buckle 22 is provided with an iron plate 222 inside the adjusting buckle 22.

[0028] The length-adjusting device 12 includes a micro controller 123, a gyroscope 124, a wireless transceiver 125, an accelerometer 126, and a battery 127 that are positioned in the inner cavity; a wafer type pressure sensor 116 positioned between a chain plate of the hinge 112 and a shaft; a platen 128, a magnet 129, and a first electromagnet 120 provided on the inner wall of the cavity of the length-adjusting device 12; and an electromagnetic array 122 disposed on the sidewalls of the second groove 121. The platen 128 is hinged to the housing. The magnet 129 and the first electromagnet 120 are respectively arranged in the housings on both sides of the hinge point of the platen 128. The platen 128 extends into the second groove 121 and contacts with the slot 21. The electromagnetic array 122 is arranged by a plurality of second electromagnets 1221 in the direction of the movement of the belt body 2.

[0029] The gyroscope 124 and the accelerometer 126 are responsible for tracking the user's motion data. The pressure sensor 116 is responsible for the detection of the force applied on the belt. Based on the principle of the interaction force, the pressure detected by the pressure sensor 116 is equal to the tension applied on the belt.

[0030] The combination of the platen 128 and the magnet 129 serves to bring one end of the platen 128 into contact with the slot 21 to lock the belt body 2 and the first electromagnet 120 is actuated to lift the platen 128 to release the belt body 2.

[0031] The electromagnet array 122 is comprised of a number of second electromagnets 1221. One or more of the second electromagnets 1221 is driven to move the adjusting buckle 22 to adjust the length of the belt until the pressure detected by the pressure sensor 116 is equal to or close to the set value. Thereafter, the one or more of the second electromagnets 1221 stops being driven, and the combination of the platen 128 and the magnet 129 locks the movement of the belt body 2.

[0032] The micro controller 123 is used to collect and process the data of the pressure sensor 116 and the counter 115, control the electromagnetic array 122, and the first electromagnet 120, and control the communication of the wireless transceiver 125 with the external device.

[0033] The center axis of the roller 113 is disposed perpendicularly to the direction of movement of the belt body 2 to ensure smooth rolling of the roller 113.

[0034] The roller 113 is made of rubber material or is provided with a rubber layer on its surface to enhance its adhesion to the belt body 2 to avoid slippage without decreasing the data accuracy.

[0035] The micro controller 123 is electrically connected to the gyroscope 124, the wireless transceiver 125, the accelerometer 126, the battery 127, the pressure sensor 116, the counter 115, the electromagnetic array 122, and the first electromagnet 120, respectively.

[0036] The length-adjusting device 12 is provided with a USB interface 1271 with a charging and discharging circuit, and the USB interface 1271 is electrically connected to the battery 127, and the USB interface 1271 can be used as a charging port for the battery 127.

[0037] The intelligent belt of the invention that automatically monitors waistline and of which the length is adjusted by the electromagnetic array, includes the buckle and the belt body. The buckle includes the waistline-measuring device, the length-adjusting device and the belt-body-fastening device. One end of the belt body is fixedly connected with the belt-body-fastening device. The other end of the belt body is provided with the adjusting buckle with the iron plate and the slot. The buckle includes the waistline-measuring device, the length-adjusting device, and the belt-body-fastening device. The housings of the waistline-measuring device, the length-adjusting device and the belt-body-fastening device are connected by hinges. The hinges are provided with the pressure sensor that is used to detect the tension applied to the belt. When a pressure value is different from a set value, the first electromagnet is controlled by the data analysis of the micro controller to lift the platen while driving a portion of magnets in the array of the electromagnets to drive the movement of the adjusting buckle on the belt body until the pressure applied on the belt reaches a range of the set values, thereby achieving the purpose of automatically adjusting the belt length. In addition, the waistline-measuring device calculates the real-time change of waistline by calculating the length of belt that passes through the first groove. The gyroscope and the accelerometer record activity data, and synchronize the real-time waistline and activity data with an external device through the wireless transceiver. It can detect physical health and activity consumption, etc. The intelligent belt has reasonable and structure, easy to use, safe, reliable, and high degree of intelligence, which effectively solve the problem regarding common belts being unable to automatically adjust the length.

[0038] The exemplary embodiments of the present invention are thus fully described. Although the description referred to particular embodiments, it will be clear to one skilled in the art that the present invention may be practiced with variations of these specific details. Hence this invention should not be construed as limited to the embodiments set forth herein.