TW202235824A - Vibration sensing and signal transmission integrated system - Google Patents

Abstract

A vibration sensing and signal transmission integrated system is configured to measure an equipment and transmit a measuring result and a vibration data to a communicating network. The vibration sensing and signal transmission integrated system includes a measuring device, a vibration sensing module and a wireless transmission module. The measuring device generates the measuring result according to the operation of the equipment. The vibration sensing module generates the vibration data according to the operation of the equipment. The wireless transmission module is coupled to the measuring device and the vibration sensing module. The wireless transmission module transmits the measuring result generated by the measuring device and the vibration data generated by the vibration sensing module to the communicating network. The vibration sensing and signal transmission integrated system not only can increase the work efficiency, but also can reduce the costs.

Description

Vibration sensing and signal transmission integrated system

The invention relates to a vibration sensing and signal transmission integration system, in particular to a vibration sensing and signal transmission integration system capable of wirelessly transmitting measurement results and vibration data of equipment.

With the development and progress of science and technology, society is gradually moving toward automation. Many devices can already replace manpower for simple and repetitive production and manufacturing operations. Furthermore, due to the development of sensors, many devices can monitor the operation of the devices through the detection or measurement of sensors. Taking groundwater as an example, water rights holders need to install water measuring equipment (such as water meters) at pumping sites, and regularly record and report pumped water to management agencies to facilitate management of groundwater use. In the traditional way of recording water pumping, the water pumping data on the water measuring equipment is usually copied manually. However, there are many problems in the way of manual meter reading, such as: the increase of labor costs, errors and omissions in meter reading, and billing doubts that cannot be resolved immediately. Therefore, a wireless transmission device was developed to automatically record and report the amount of water pumped.

In the traditional wireless transmission equipment, another equipment box needs to be installed next to the water measuring equipment. The wireless transmission module is installed in the equipment box, and the wireless transmission module and the water measuring equipment need to be connected with a signal line to capture the water pumping data. Further, since the wireless transmission equipment needs power supply for Therefore, it is necessary to pull a power source (such as mains power) to the wireless transmission device. In addition, because the water pumping equipment and water measuring equipment may be far away from the factory or farmland, and most of the wireless transmission equipment is installed on the ground and exposed to the external environment, so the power cord is not easy to configure and install on the wireless transmission equipment, not only Increases material costs and reduces safety.

Although some traditional wireless transmission devices use batteries instead of power cords to provide power, most of the traditional wireless transmission devices use 3G and 4G wireless transmission methods to transmit water pumping data. Due to the high power consumption required by the 3G or 4G transmission mode, the battery must be replaced frequently to maintain the transmission function of the wireless transmission device.

Therefore, a new wireless transmission device is needed to solve the above-mentioned problems.

Therefore, the present invention provides an integrated vibration sensing and signal transmission system to solve the problems of the prior art.

The vibration sensing and signal transmission integration system of the present invention is used for measuring equipment and transmitting the measurement results and vibration data to the communication network. The vibration sensing and signal transmission integrated system includes a measuring device, a vibration sensing module and a wireless transmission module. The measuring device includes a casing with an accommodating space. The measurement device generates measurement results according to the operation of the equipment. The vibration sensing module is coupled to the device and generates vibration data according to the operation of the device. The wireless transmission module is arranged in the accommodation space and coupled to the measuring device and the vibration sensing module. The wireless transmission module is used for transmitting the measurement results generated by the measuring device and the vibration data generated by the vibration sensing module to the communication network.

Further, the vibration sensing and signal transmission integrated system includes a power module disposed in the accommodation space and electrically coupled to the wireless transmission module. The power module is used to provide power to drive the wireless transmission module.

Wherein, the power provided by the power supply module is greater than the power consumption required by the wireless transmission module.

Wherein, the battery module is a storage battery, and the wireless transmission module is NB-IoT.

Further, the integrated system of vibration sensing and signal transmission includes a solar module disposed on the outside of the casing and coupled to the battery. The solar module is used to generate electric energy, and the battery stores the electric energy generated by the solar module.

Further, the integrated vibration sensing and signal transmission system includes an antenna. The antenna is arranged outside the housing and coupled to the wireless transmission module. The wireless transmission module transmits the measurement results to the communication network through the antenna.

Furthermore, the vibration sensing and signal transmission integrated system includes a magnetic field sensing module coupled with a measuring device and a wireless transmission module. The magnetic field sensing module generates a measurement result signal according to the measurement result generated by the measurement device, and transmits the measurement result signal to the wireless transmission module.

Further, the vibration sensing and signal transmission integrated system includes a memory and a processor. The storage is arranged in the accommodating space and coupled to the measuring device. The processor is arranged in the accommodating space and coupled to the storage and the wireless transmission module. The memory is used to store the measurement results generated by the measuring device, and the processor controls the wireless transmission module to transmit the measurement results stored in the memory to the communication network at intervals.

Wherein, the material of the shell is waterproof material.

To sum up, the present invention provides an integrated vibration sensing and signal transmission system that can automatically and wirelessly transmit the measurement results and data of the equipment through the wireless transmission module, and can generate electric energy through the power supply module and the solar module. achieve self-sufficiency. In addition, the integrated system of vibration sensing and signal transmission can not only control the cycle of vibration data transmission, but also The motion sensing module monitors whether the equipment is faulty. Therefore, the integrated vibration sensing and signal transmission system of the present invention can not only improve efficiency and safety, but also reduce material and labor costs.

1: Vibration sensing and signal transmission integrated system

11: Measuring device

111: shell

112: Flow detector

12: Wireless transmission module

121: Wireless transmission chip

122: circuit board

13: Power module

14: Solar module

15: Antenna

16: Magnetic field sensing module

17: Vibration sensing module

18: Storage

19: Processor

2: Water storage device

3: Pumping equipment

4: water pipe

5: Communication network

A:Accommodating space

FIG. 1 shows a functional block diagram of an integrated vibration sensing and signal transmission system according to an embodiment of the present invention.

FIG. 2 is a schematic structural diagram of the vibration sensing and signal transmission integrated system shown in FIG. 1 .

FIG. 3 shows a functional block diagram of an integrated vibration sensing and signal transmission system according to an embodiment of the present invention.

FIG. 4 is a schematic structural diagram of an integrated vibration sensing and signal transmission system according to an embodiment of the present invention.

FIG. 5 shows a functional block diagram of the integrated vibration sensing and signal transmission system of FIG. 5 .

FIG. 6 is a functional block diagram of another embodiment of the vibration sensing and signal transmission integration system shown in FIG. 4 .

In order to make the advantages, spirit and characteristics of the present invention more easily and clearly understood, the following will be described and discussed in detail with reference to the accompanying drawings. It should be noted that these examples are only representative examples of the present invention. It can however be implemented in many different forms and is not limited to the embodiments described in this specification. Rather, these embodiments are provided so that the disclosure of the invention will be thorough and complete.

In the description of this specification, descriptions referring to the terms "an embodiment", "a specific embodiment" and the like mean that specific features, structures, materials or characteristics described in conjunction with the embodiment include In at least one embodiment of the invention. In this specification, the schematic representations of the above terms do not necessarily refer to the same embodiment. Furthermore, the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments.

In the description of the present invention, unless otherwise stipulated or limited, it should be explained that the terms "coupled", "connected" and "arranged" should be understood in a broad sense, for example, it can be a mechanical connection or an electrical connection, or it can be two The internal communication of each element may be directly connected or indirectly connected through an intermediary. Those skilled in the art can understand the specific meanings of the above terms according to specific situations.

Please refer to Figure 1 and Figure 2. FIG. 1 shows a functional block diagram of an integrated vibration sensing and signal transmission system according to an embodiment of the present invention. FIG. 2 is a schematic structural diagram of the vibration sensing and signal transmission integrated system shown in FIG. 1 . As shown in FIG. 1 and FIG. 2 , the integrated vibration sensing and signal transmission system 1 of the present invention includes a measuring device 11 , a vibration sensing module 12 and a wireless transmission module 13 . The measuring device 11 and the vibration sensing module 12 are coupled to the device 3 , and the wireless transmission module 13 is coupled to the measuring device 11 , the vibration sensing module 12 and the communication network 5 . The measurement device 11 generates measurement results according to the operation of the device 3, the vibration sensing module 12 generates vibration data according to the operation of the device 3, and the wireless transmission module 13 is used to transmit the measurement results generated by the measurement device 11 and The vibration data generated by the vibration sensing module 12 is sent to the communication network 5 .

The vibration sensing and signal transmission integration system 1 of the present invention can be applied to various vibration equipment or devices. The following will take pumping equipment as an example. In practice, the integrated vibration sensing and signal transmission system 1 of the present invention can be coupled to the pumping equipment and the water storage device. Further, the integrated vibration sensing and signal transmission system 1 is connected to the pumping equipment and the water storage device through water pipes. The equipment 3 can be a water pumping equipment (such as: a water pumping motor), and can be installed in a water well or a ground water pumping station to pump ground water. water storage The device can be a water tower for a factory or a reservoir for an agricultural field, and can be used to store groundwater pumped by a pumping motor. The groundwater pumped by the water pumping motor can be transported to the water storage device through the water pipe. The measuring device 11 of the integrated vibration sensing and signal transmission system 1 can be a water measuring device and can be installed on a water pipe, or can be connected to the water pipe between the device 3 and the water storage device by cutting a pipe. Furthermore, the measuring equipment 11 of the integrated vibration sensing and signal transmission system 1 can be installed at any section or position of the water pipe. In addition, the integrated vibration sensing and signal transmission system 1 can communicate with the communication network 5 . In practice, the communication network 5 can be a cloud or a communication base station. Therefore, the integrated vibration sensing and signal transmission system 1 can measure the pumping data of the pumping motor when groundwater flows through the water pipe, and can transmit the pumping data of the pumping motor to the communication network 5 .

In practice, the measuring device 11 can be a mechanical water meter or an electronic water meter. Furthermore, the measuring device 11 can also be an ultrasonic or electromagnetic electronic water meter, but it is not limited thereto. The measuring device 11 can be arranged on the water pipe and connected to the pumping motor through the water pipe. The measuring device 11 may include a flow detector 112 . The flow detector 112 is used to measure the flow of groundwater passing through the water pipe. When the groundwater pumped by the pumping motor flows through the water pipe, the flow detector 112 of the measuring device 11 calculates the pumping amount of the groundwater pumped by the pumping motor according to the flow velocity of the groundwater and the size of the water pipe and generates a pumping result. Further, the flow detector 112 can convert the pumping result into a value according to different methods. For example, when the measuring device 11 is a mechanical water meter, the flow detector 112 can be a mechanical element in the mechanical water meter. The mechanical water meter pushes the mechanical element located in the water pipe according to the water flowing through the water pipe, and then drives the pointer on the water meter to measure the water pumped. The flow detector of the mechanical water meter may further include a counting device (such as a counter). The counting device can use the pointer to convert the measured pumping volume into pumping data. When the measuring device 11 is an ultrasonic electronic water meter, the flow detector 112 can be an ultrasonic transceiver. The ultrasonic electronic water meter is based on the time between ultrasonic sending and receiving when water flows through the water pipe. The time difference measures the water pumping amount, and the flow detector 112 may further include data conversion electronic components to convert the water pumping amount into water pumping data. In practice, the vibration sensing module 12 can be an acceleration sensor (G-sensor). When the water pumping equipment starts, the acceleration sensor can generate vibration data according to the vibration of the water pumping equipment and transmit the vibration data to the wireless transmission module 13 .

The wireless transmission module 13 can be a wireless transmission chip integrated on a circuit board, or a circuit module including a circuit board and wireless transmission electronic components. The wireless transmission module 13 can be electrically connected to the flow detector 112 of the measuring device 11 to transmit the pumping result measured by the flow detector 112 to the communication network 5 . In a specific embodiment, the measurement device 11 may also include a flow detector 112 connected to a circuit board. The wireless transmission module 13 can be electrically connected to the circuit board to transmit the pumping results measured by the flow detector 112 to the communication network 5 . In this specific embodiment, the wireless transmission module 13 is coupled to the measurement device 11 and communicates with the communication network 5 in a wireless transmission manner. In practice, the wireless transmission method can be 3G, 4G, Bluetooth, NFC, Wi-Fi, ZigBee, NB-IoT, or any near-field or far-field wireless transmission. Therefore, when the measuring device 11 generates pumping results according to the operation of the pumping equipment, the wireless transmission module 13 can transmit the pumping results to the communication network 5 .

As shown in Figure 1 and Figure 2, since the pumping motor may be far away from the factory or farmland, and the measuring device may need to be replaced regularly due to long-term use, most of the wireless transmission equipment is installed on the ground or exposure to the external environment. In this specific embodiment, the measurement device 11 of the integrated vibration sensing and signal transmission system 1 includes a casing 111 with an accommodating space A, and the wireless transmission module 13 is disposed in the accommodating space A. In practice, the housing 111 of the measuring device 11 can be fixed on the water pipe to measure the pumping capacity of the pumping motor. Since the wireless transmission module 13 is an electronic component, the wireless transmission module 13 can be disposed in the accommodating space A of the housing 111 to prevent interference from the external environment (such as rain or sun exposure). In a specific embodiment, the material of the housing 111 The quality is waterproof material. Therefore, regardless of whether the measuring device 11 of the integrated vibration sensing and signal transmission system 1 is installed underground, on the ground or exposed to the external environment, the housing 111 of the measuring device 11 can prevent the infiltration of moisture from the outside to maintain the wireless transmission mode. Group 13 operates and avoids short circuits, thereby improving efficiency and safety.

In addition to the fact that the pumping motor may be far away from the factory or farmland, the integrated vibration sensing and signal transmission system 1 may also be far away from the communication network 5 . In this specific embodiment, the vibration sensing and signal transmission integrated system 1 includes an antenna 16 coupled to the housing 111 of the measurement device 11 and a wireless transmission module 13, and the wireless transmission module 13 transmits to the communication network 5 through the antenna 16 . In practice, the antenna 16 can be fixed on the casing 111 and one end thereof extends out of the casing 111 , while the other end of the antenna 16 is coupled to the wireless transmission module 13 . When the wireless transmission module 13 transmits the pumping result signal to the communication network 5, the antenna 16 can enhance the signal strength. Therefore, the antenna 16 can not only prevent the water pumping result signal transmitted by the wireless transmission module 13 from being weakened due to being shielded by the casing 111 , but also increase the transmission distance of the water pumping result signal. In addition, the antenna 16 can also be disposed on the casing 111 at an angle. In practice, the antenna 16 may include a rotating structure. When the integrated vibration sensing and signal transmission system 1 is installed on a water pipe, the installation angle of the antenna 16 can also be adjusted to increase the strength of the signal transmitted by the wireless transmission module 13 . Therefore, the vibration sensing and signal transmission integrated system 1 can increase the signal strength and signal transmission distance of the pumping result through the antenna 16 to improve efficiency.

Since the wireless transmission module 13 is composed of electronic components, energy needs to be applied to the wireless transmission module 13 to drive the wireless transmission module 13 to transmit the pumping results to the communication network 5 . In this specific embodiment, the vibration sensing and signal transmission integrated system 1 includes a power module 14 coupled to the wireless transmission module 13 and used to provide power to drive the wireless transmission module 13 . In practice, the power module 14 can be an AC module and includes a power cord. One end of the power cord can be coupled to the vibration sense The wireless transmission module 13 of the measurement and signal transmission integration system 1, and the other end is connected to the distribution box. Therefore, the wireless transmission module 13 can operate and transmit the pumping results to the communication network 5 through the electric energy provided by the power line. Further, a transformer (not shown) may be included between the wireless transmission module 13 and the power module 14 . In practice, the transformer can be disposed in the casing 111 . When the power module 14 provides electric energy to the vibration sensing and signal transmission integrated system 1 , the transformer can convert the electric energy to the electric energy required by the wireless transmission module 13 , so that the wireless transmission module 13 transmits the pumping results to the communication network 5 .

Please refer to Figure 3. FIG. 3 shows a functional block diagram of a vibration sensing and signal transmission integrated system 1 according to a specific embodiment of the present invention. In addition to the aforementioned measuring device 11 including a counting device to generate water pumping data, it may also include other forms. As shown in FIG. 3 , the vibration sensing and signal transmission integrated system 1 includes a magnetic field sensing module 17 coupled to the measurement device 11 and a wireless transmission module 13 . The magnetic field sensing module 17 generates a pumping result signal according to the pumping result generated by the measuring device 11 , and transmits the pumping result signal to the wireless transmission module 13 . In practice, the magnetic field sensing module 17 can be a Hall sensor. When the measuring device 11 is a mechanical water meter, the Hall sensor can be disposed on the head of the mechanical water meter. The pointer of the mechanical water meter can be equipped with magnetic elements. When the pointer of the mechanical water meter rotates and passes the Hall sensor, the Hall sensor can convert the potential difference generated by the passing of the pointer into a pumping result signal. Then, the Hall sensor transmits the water pumping result signal to the wireless transmission module 13 .

Please refer to Figure 4 and Figure 5. FIG. 4 shows a schematic structural diagram of an integrated vibration sensing and signal transmission system 1 according to a specific embodiment of the present invention, and FIG. 5 shows a functional block diagram of the integrated vibration sensing and signal transmission system 1 in FIG. 4 . The power supply module 14 can also be in other forms besides the aforementioned forms. In a specific embodiment, the power supply module 14 is a battery. Further, the power provided by the power supply module 14 is greater than the power consumption required by the wireless transmission module 13 . In practice, the power module 14 It can be a carbon-zinc battery, an alkaline battery, a hydrogen-oxygen battery, a mercury battery, a silver battery, or other primary batteries, and the number of batteries can be more than one. The battery is disposed in the casing 111 of the measuring device 11 and connected to the wireless transmission module 13 , so the wireless transmission module 13 can operate with the energy provided by the battery and transmit the pumping results to the communication network 5 . The wireless transmission module 13 can be an NB-IoT module. Since the NB-IoT module has the function of low-power wide-area transmission, compared with the conventional technology, the power consumption of the NB-IoT module is lower than that consumed by the traditional wireless transmission module. Accordingly, the vibration sensing and signal transmission integrated system 1 can maintain a longer operating time and reduce the number of battery replacements, thereby reducing costs.

In another specific embodiment, the power supply module 14 is a storage battery, and the integrated vibration sensing and signal transmission system 1 includes a solar module 15 . In practice, the power module 14 can be a lead battery, a lithium battery, a nickel metal hydride battery, a nickel cadmium battery, or other secondary batteries. The solar module 15 can be a solar panel, and can also be designed according to user requirements. The number of solar modules 15 is not limited to one, and may be more than one. The solar module 15 can be fixed outside the casing 111 of the measuring device 11 to receive sunlight and generate electricity. The storage battery is disposed in the housing 111 of the measuring device 11 and connected to the wireless transmission module 13 and the solar module 15 . When the solar module 15 absorbs sunlight and generates electric energy, the battery stores the electric energy generated by the solar module 15 and provides the electric energy to the wireless transmission module 13 to drive the wireless transmission module 13 to transmit the pumping results to the communication network 5 . In addition, when the wireless transmission module 13 is an NB-IoT module, the electric energy generated by the solar module 15 can be greater than the power consumption required by the NB-IoT module. Therefore, the vibration sensing and signal transmission integrated system 1 can continuously Generating electric energy efficiently to supply the wireless transmission module 13 not only improves the efficiency but also reduces the cost.

Please refer to Figure 4 and Figure 6. FIG. 6 shows a functional block diagram of the vibration sensing and signal transmission integration system 1 of another embodiment shown in FIG. 4 . As shown in Figure 4 and Figure 6, vibration sensing and signal The transmission integration system 1 includes a storage 18 and a processor 19 . The storage 18 is coupled to the measuring device 11 , and the processor 19 is coupled to the storage 18 and the wireless transmission module 13 . In practice, the storage 18 can be a USB, an external hard disk or a storage chip, and the processor 19 can be a central processing unit. The storage 18, the processor 19 and the wireless transmission module 13 can be integrated on the circuit board, or the storage 18 and the processor 19 can be integrated on the circuit board and connected to the wireless transmission module 13, but not limited thereto. The storage 18 stores the pumping results generated by the measuring device 11 , and the processor 19 controls the wireless transmission module 13 to transmit the pumping results stored in the storage 18 to the communication network 5 at intervals. In practice, the measuring device 11 can generate water pumping results in a fixed period (for example, generate a water pumping result every 30 minutes), and the storage 18 can store all the water pumping results generated by the measuring device 11 . The processor 19 can control the wireless transmission module 13 to transmit the water pumping results at intervals according to preset intervals according to requirements. For example, when the pumping motor used by the water users in the factory or farmland needs to read the water meter every month, the processor 19 of the vibration sensing and signal transmission integrated system 1 can control the wireless transmission module 13 to transmit every 30 days The pumping results stored in the storage 18 are sent to the communication network 5 . Therefore, the vibration sensing and signal transmission integrated system 1 can automatically transmit the water pumping results according to the demand and the set time, so as to reduce labor costs.

Besides being directly connected to the wireless transmission module 13 , the vibration sensing module 12 may also be coupled to the aforementioned storage and processor (not shown). The functions of the storage and the processor in this specific embodiment are the same as those of the storage and the processor in the foregoing specific embodiments, and will not be repeated here. In practice, the vibration sensing module 12 can store the vibration data in a memory, and the processor can control the wireless transmission module 13 to transmit the vibration data within a period of time to the communication network 5 . Therefore, water users in factories and farmland can monitor whether the pumping motor is faulty or damaged through the vibration data transmitted by the integrated vibration sensing and signal transmission system 1 .

In summary, the present invention provides an integrated vibration sensing and signal transmission system that can be transparently The measurement results and data of the equipment are automatically transmitted wirelessly through the wireless transmission module, and the power supply module can be combined with the solar module to generate electric energy to achieve self-sufficiency. In addition, the integrated system of vibration sensing and signal transmission can not only control the cycle of vibration data transmission, but also monitor whether the equipment is faulty through the vibration sensing module. Therefore, the integrated vibration sensing and signal transmission system of the present invention can not only improve efficiency and safety, but also reduce material and labor costs.

Through the above detailed description of the preferred embodiments, it is hoped that the characteristics and spirit of the present invention can be described more clearly, and the scope of the present invention is not limited by the preferred embodiments disclosed above. On the contrary, the intention is to cover various changes and equivalent arrangements within the scope of the patent application for the present invention. Therefore, the scope of the scope of the patent application for the present invention should be interpreted in the broadest way based on the above description, so as to cover all possible changes and equivalent arrangements.

1: Vibration sensing and signal transmission integrated system

11: Measuring device

12: Vibration sensing module

13: Wireless transmission module

3: Equipment

5: Communication network

Claims (9)

An integrated vibration sensing and signal transmission system is used to measure a device and transmit a measurement result and a vibration data to a communication network. The vibration sensing and signal transmission integrated system includes: a measuring device, coupled to the device and comprising a housing with an accommodating space, the measuring device generates the measurement result according to the operation of the device; a vibration sensing module, coupled to the device and generating the vibration data according to the operation of the device; and A wireless transmission module, arranged in the accommodation space and coupled to the measurement device and the vibration sensing module, the wireless transmission module is used for the measurement result generated by the measurement device and the vibration The vibration data generated by the sensing module is transmitted to the communication network. The vibration sensing and signal transmission integrated system described in item 1 of the scope of the patent application further includes a power module arranged in the accommodating space and electrically coupled to the wireless transmission module, the power module is used to provide a Electric energy drives the wireless transmission module. In the vibration sensing and signal transmission integrated system described in item 2 of the scope of the patent application, the power provided by the power supply module is greater than the power consumption required by the wireless transmission module. The vibration sensing and signal transmission integrated system described in item 2 of the scope of the patent application, wherein the power supply module is a storage battery, and the wireless transmission module is NB-IoT. The vibration sensing and signal transmission integrated system described in item 4 of the scope of the patent application further includes a solar module arranged on the outside of the casing and coupled to the battery, the solar module is used to generate the electric energy, and the The storage battery stores the electric energy generated by the solar module. The vibration sensing and signal transmission integrated system described in item 1 of the scope of the patent application further includes an antenna, the antenna is arranged on the outside of the housing and coupled to the wireless transmission module, and the wireless transmission module passes through the antenna transmitting the measurement result and the vibration data to the communication network. The vibration sensing and signal transmission integrated system described in item 1 of the scope of the patent application further includes a magnetic field sensing module coupled to the measurement device and the wireless transmission module, and the magnetic field sensing module is based on the measurement The measurement result generated by the device generates a measurement result signal, and transmits the measurement result signal to the wireless transmission module. The vibration sensing and signal transmission integrated system described in item 1 of the scope of the patent application further includes a storage and a processor, the storage is arranged in the accommodating space and coupled to the measuring device, the processor Set in the accommodation space and coupled with the storage and the wireless transmission module, the storage is used to store the measurement results generated by the measuring device, and the processor controls the wireless transmission module at each interval Transmitting the measurement result stored in the memory to the communication network for a period of time. In the vibration sensing and signal transmission integrated system described in Item 1 of the scope of the patent application, the housing is made of waterproof material.

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