Wireless Appliance Vibration Sensor Monitor And Method

Abstract

The apparatus disclosed is a wireless vibration sensor monitor and recorder along with the associated system and method of use. The apparatus contains a digital accelerometer that operates off six axes. The apparatus may also include features such as a temperature sensor and ambient light sensor. The system actively monitors time and battery voltage level, as well as records information pertinent to the health of the apparatus. Once affixed to an appliance or piece of machinery, the apparatus monitors the duration of the cycle and the vibrations produced to compile a cycle profile. Once the apparatus has determined the cycle or predetermined period to be complete, a notification is sent to a remote user. This signal may be received by any compatible Bluetooth low energy device.

Claims

1. A wireless vibration sensor and monitor comprising: an external casing, the external casing having at least two sections with the at least two sections connected to one another forming a hollow interior and housing an accelerometer, a printed circuit board, a wireless low power transceiver, an application microcontroller, and a battery.

2. The wireless vibration sensor and monitor of claim 1 further comprising a temperature sensor.

3. The wireless vibration sensor and monitor of claim 1 further comprising a light sensor.

4. The wireless vibration sensor and monitor of claim 1 further comprising a carrier.

5. The wireless vibration sensor and monitor of claim 4 wherein the carrier has at least one fingernail release tab.

6. The wireless vibration sensor and monitor of claim 2 wherein the sensitivity of the temperature sensor is user configurable.

7. The wireless vibration sensor and monitor of claim 3 wherein the sensitivity of the light sensor is user configurable.

8. The wireless vibration sensor and monitor of claim 1 wherein the sensitivity of the analog input is user configurable.

9. The wireless vibration sensor and monitor of claim 1 wherein the accelerometer is a digital accelerometer operating on six axes.

10. The wireless vibration sensor and monitor of claim 9 wherein the sensitivity of the accelerometer is user configurable.

11. The wireless vibration sensor and monitor of claim 1 further comprising at least one configurable button.

12. The wireless vibration sensor and monitor of claim 1 further comprising at least one light emitting diode (LED).

13. The wireless vibration sensor and monitor of claim 1 wherein the external casing comprises IP68 compliant plastic.

14. The wireless vibration sensor and monitor of claim 13 wherein at least one tab protrudes from the external surface of the external casing.

15. The wireless vibration sensor and monitor of claim 14 wherein at least two analog to digital converting (ADC) metal contact pins protrude from the interior surface of the external casing.

16. An appliance monitoring system comprising: a wireless vibration sensor and monitor, the wireless vibration sensor and monitor having an external casing, the external casing having at least two sections with the at least two sections connected to one another and housing an accelerometer, a printed circuit board, a wireless low power transceiver, an application microcontroller, and a battery; and a Bluetooth low energy device by which a remote user can interact with and communicate with the wireless vibration sensor and monitor.

17. The appliance monitoring system of claim 16 wherein the Bluetooth low energy device is a smart phone.

18. The appliance monitoring system of claim 16 wherein the system operates over the 2.4 GHz microwave band spectrum.

19. The appliance monitoring system of claim 18 wherein the system employs secured encrypted point-to-point communication and frequency hopping spread spectrum (FHSS) communication.

20. A method of using a wireless vibration sensor and monitor comprising: attaching the wireless vibration sensor and monitor to a desired appliance; setting the vibration sensitivity level to correspond to the desired appliance; monitoring the vibration level and active time period; and sending a wireless signal to a dedicated Bluetooth low energy device upon meeting predetermined thresholds.

21. The method of claim 20 wherein the wireless vibration sensor and monitor is attached to an appliance with an adhesive.

22. The method of claim 20 wherein the remote user can set or change the sensitivity settings.

23. The method of claim 22 wherein software enables the remote user to configure the settings wirelessly.

24. The method of claim 23 wherein the software may be updated wirelessly.

25. The method of claim 20 wherein the wireless signal contains a data packet comprising time, battery voltage, sensitivity, appliance health, light, tilt, analog input, or temperature information.

Description

BRIEF DESCRIPTIONS OF DRAWINGS

[0013] Preferred embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:

[0014] FIG. 1 illustrates a view of a fully assembled apparatus of a preferred embodiment.

[0015] FIG. 2 illustrates a top view of the disassembled exterior components of a preferred embodiment.

[0016] FIG. 3 illustrates a bottom view of the lower disassembled exterior components of a preferred embodiment.

[0017] FIG. 4 is a flow chart demonstrating a method of use of a preferred embodiment.

DETAILED DESCRIPTION

[0018] Referring to the drawings, FIG. 1 refers to a preferred embodiment of a fully assembled apparatus, The top half of the external casing 2 is joined with the lower half of the external casing 4 to form the outer protective casing of the apparatus, and the internal components are contained therein. The top half of the external casing 2 and lower half of the external casing 4 are formed from an IP68 compliant plastic. The joint between the two halves is protected by an O-ring 6. The O-ring 6 can comprise different materials. These materials are selected based on chemical compatibility, operating temperature, sealing pressure, size, and cost.

[0019] On one half of the protective casing, there are at least one protrusion(s) from the external casing. These tabs 8 enable the user to grip the external casing and aid the user in moving or manipulating the external casing. The tabs 8 may be formed as part of the external casing as a whole. In other embodiments, the tabs 8 are of a separate material adhered to the surface of the external casing. The external casing fits snugly into a carrier 10. The carrier 10 has a tab 14 and at least one fingernail release 12 to aid the user in removing the apparatus from the carrier 10. The tab 14 enables the user to hang the apparatus or gives extra aid in handling, moving, or manipulating the apparatus.

[0020] FIG. 2 depicts the preferred embodiment of the exterior components in their disassembled form. The top half of the external casing 2 is separated from the lower half of the external casing 4. Inside the lower half of the external casing 4 is a support tab 16. The support tab 16 provides stability and support, as well as enabling the user to move or manipulate the interior components of the apparatus. The interior surface also includes at least two protruding analog to digital converting (ADC) metal contacts 20. The ADC metal contacts 20 utilize an analog to digital voltage differential input to determine the presence of water within the external casing. The O-ring 6 can be settled on either half of the external casing. The fingernail release(s) 12 are visible and demonstrate how one may manipulate them in such a way by bending slightly outward as to release the external casing.

[0021] In FIG. 3, the underside of the lower half of the external casing 4 contains a slot 18. The slot 18 is designed to interact with a coin or other similar edge in order to enable the user to separate the halves of the external casing in order to perform maintenance or manipulate the interior components of the apparatus. In some embodiments, the external casing may have grooves that lock the lower half of the external casing 4 and upper half of the external casing 2 by way of a clockwise or counterclockwise twisting motion. In other embodiments, the surfaces are smooth and fit together snugly due to a minute sizing differential between the two halves.

[0022] FIG. 4 is a flow chart that refers to a preferred method of use for the apparatus. The user attaches the apparatus to the desired appliance 202. This appliance can be any number of types of machinery notably that put out most any type of vibration. Once the apparatus is attached to the desired appliance or machinery, the user the selects the vibration setting for the apparatus 204. This setting can be manipulated either manually or by the remote user using their Bluetooth receiver. The associated software may also provide for predetermined settings for measurable variables based on the make/model of the appliance. Additionally, this software may be updated wirelessly as new versions become available.

[0023] The Bluetooth receiver held and employed by the remote user can be any number of compatible items including, but not limited to, smart phones or other Bluetooth low energy compatible devices. This enables a wide range usage rather than only having its functionality tied to a particular system. The alerts or notifications sent to the user can take the form of any one or a combination of the following: vibrations, audible, SMS, or email. This removes undue costs and allows users to receive notifications on systems they are previously familiar and in turn have virtually no learning curve.

[0024] This enables the user to pick from predetermined or their own settings and to fine tune them to best achieve the desired results. The apparatus then monitors the time and vibration activity of the cycle of the appliance 206. The time and vibration, or lack their off, throughout the cycle is used to determine when the cycle is complete without the worry of sending a false signal to the remote user. When the cycle does complete, a wireless signal is sent from the apparatus to the remote user 208. This signal can take many forms including audio tones, visual cues, vibrations, or emails.