CN112345099B - Wireless temperature sensor for monitoring electric power temperature - Google Patents

Abstract

The invention discloses a wireless temperature sensor for monitoring electric power temperature, which comprises a shell and a fixing assembly, wherein the shell comprises an installation opening arranged at the bottom of the shell, and the fixing assembly comprises a connecting piece and a lengthening block. According to the device, the lengthening blocks are matched with the connecting piece, and a plurality of groups of lengthening blocks are arranged, so that the mounting requirements of different devices to be tested are met, the length of the connecting belt is adjusted, and the practicability of the device when being matched with different devices is improved. Each lengthening block can be connected with the connecting piece and is arranged on the device to be tested, so that the device is convenient to mount and dismount, and the time is saved. Through two kinds of cooperation modes, adjust the elasticity degree of connecting band, make the better laminating of measuring module surveyed the device, make measuring result more accurate.

Description

Wireless temperature sensor for monitoring electric power temperature

Technical Field

The invention relates to the technical field of power temperature detection, in particular to a wireless temperature sensor for power temperature monitoring.

Background

The wireless temperature sensor is a wireless sensor network product integrating the technologies of sensing, wireless communication, low power consumption and the like, the wireless temperature sensor is powered by a battery, laying of communication cables, pipelines and power supply lines with large workload is avoided in engineering implementation, and a user can conveniently adjust the installation position according to the actual use condition on site. In industry and electric power industry, the normal operating of electrical equipment has guaranteed the normal operation of society and the normal life of people, therefore the reliability of equipment is vital, the temperature is the most important control parameter in the preventive maintenance, too high or too low of temperature all means the possibility that the trouble produced, realize that temperature on-line monitoring is the important means of guaranteeing high-voltage apparatus safe operation, therefore it is very necessary to utilize wireless temperature sensing device to carry out real time monitoring to the temperature of equipment, current wireless temperature sensing device can be divided into screw and watchband formula two kinds, current watchband formula wireless temperature sensing device has the defect that watchband length can't be adjusted, thereby can not effectually carry out the installation work according to the size of being detected equipment pipeline diameter, the practicality when having reduced the device and matching different equipment, inconvenient use.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made in view of the above and/or problems occurring in the conventional wireless temperature sensors for power temperature monitoring.

Therefore, the invention aims to solve the problems that the length and the tightness of the connecting belt of the wireless temperature sensor cannot be adjusted according to a measured device, and the connecting belt cannot be installed and used for different equipment.

In order to solve the technical problems, the invention provides the following technical scheme: a wireless temperature sensor for monitoring electric power temperature comprises a shell, a temperature sensor and a temperature sensor, wherein an accommodating space is formed in the shell and comprises a mounting hole arranged at the bottom of the shell; and the fixing component is arranged in the mounting opening, and the two ends of the fixing component extend out of the mounting opening.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the connecting piece is including setting up in the first connection end of its one end, setting up in the first cooperation board of its other end to and the mounting panel of being connected with first connection end and first cooperation board.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the first connecting end comprises a lug arranged at the top of the first connecting end, a matching groove arranged at the bottom of the lug and an L-shaped through groove arranged in the middle of the lug; the first matching board comprises a spring arranged at the top of the first matching board, a baffle connected with the spring, a square through groove arranged on the baffle, a square block matched with the square through groove, and a built-in block matched with the first connecting end.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the built-in block comprises a matching convex block matched with the matching groove and a groove matched with the convex block.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the lengthening blocks are provided with a plurality of groups, and comprise second connecting end heads arranged at the tops of the lengthening blocks and second matching plates connected with the second connecting end heads; the second connecting end is consistent with the first connecting end structure, and the second matching plate is consistent with the first matching plate structure.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the shell further comprises a wireless temperature measuring module, a microprocessor module and a wireless transmitting module which are arranged in the accommodating space.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the wireless temperature measurement module is connected with the microprocessor module, and the microprocessor module is connected with the wireless transmitting module.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the shell further comprises a temperature measuring probe connected with the wireless temperature measuring module and a detecting hole matched with the temperature measuring probe.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the spring, the baffle, the square block and the built-in block are all arranged in the inner cavity of the first matching plate.

As a preferable aspect of the wireless temperature sensor for power temperature monitoring of the present invention, wherein: the shell further comprises inserting ports arranged at the top of the shell, and at least two groups of inserting ports are arranged.

The invention has the advantages that the matching of the lengthening blocks and the connecting pieces and the installation of a plurality of groups of lengthening blocks can meet the installation requirements of different devices to be tested, realize the adjustment of the length of the connecting band and improve the practicability of the device when being matched with different devices. Each lengthening block can be connected with the connecting piece and is arranged on the device to be tested, so that the device is convenient to mount and dismount, and the time is saved. Through two kinds of cooperation modes, adjust the elasticity degree of connecting band, make the better laminating of measuring module surveyed the device, make measuring result more accurate.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor. Wherein:

fig. 1 is a scene diagram of a wireless temperature sensor for power temperature monitoring.

Fig. 2 is a block diagram of a wireless temperature sensor for power temperature monitoring.

Fig. 3 is a block diagram of a mounting assembly of a wireless temperature sensor for power temperature monitoring.

FIG. 4 is a diagram of a fixed assembly and an elongated block of a wireless temperature sensor for power temperature monitoring.

FIG. 5 is a cross-sectional view of a mounting assembly and extension block of a wireless temperature sensor for power temperature monitoring.

FIG. 6 is a cross-sectional view of a first snap-in version of a wireless temperature sensor for power temperature monitoring.

FIG. 7 is a cross-sectional view of a second snap-in version of a wireless temperature sensor for power temperature monitoring.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced otherwise than as specifically described herein, and it will be appreciated by those skilled in the art that the present invention may be practiced without departing from the spirit and scope of the present invention and that the present invention is not limited by the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 7, for a first embodiment of the present invention, the embodiment provides a wireless temperature sensor for power temperature monitoring, the wireless temperature sensor for power temperature monitoring includes a housing 100 and a fixing assembly 200, the fixing assembly 200 is disposed at the bottom of the housing 100, the fixing assembly 100 includes a connecting member 201 and an extension block 202, the connecting member 201 can be connected at the front end and the rear end to realize fixing, and the extension block 202 can be additionally installed to realize length adjustment on the premise that the housing is fixed by the connecting member 201, so as to meet fixing requirements of different devices to be measured.

Specifically, the housing 100, which has an accommodating space M formed therein, includes a mounting opening 101 disposed at the bottom of the housing 100, and the mounting opening 101 is disposed to be connected to the fixing component 200, so as to fix the sensor to the device to be tested.

The fixing assembly 200, which is disposed in the mounting opening 101 and has two ends extending out of the mounting opening 101, includes a connecting member 201 disposed at one end of the housing 100 and an elongated block 202 engaged with the connecting member 201. Through connecting piece 201 end to end, can fix the sensor on being surveyed the device, extension piece 202 can set up to the multiunit according to the device being surveyed of difference, and every group extension piece 202 all can be connected with connecting piece 201 one end, according to being surveyed the device, dismantles or increases the extension piece, realizes the regulation to length to simple to operate, convenient to detach practices thrift a large amount of time.

Further, the connection member 201 includes a first connection end 201a disposed at one end thereof, a first mating plate 201b disposed at the other end thereof, and a mounting plate 201c connected to the first connection end 201a and the first mating plate 201 b. The first connection terminal 201a comprises a bump 201a-1 arranged at the top thereof, a matching groove 201a-2 arranged at the bottom of the bump 201a-1, and an L-shaped through groove 201a-3 arranged in the middle of the bump 201 a-1; the first matching plate 201b comprises a spring 201b-1 arranged at the top of the first matching plate, a baffle plate 201b-2 connected with the spring 201b-1, a square through groove 201b-3 arranged on the baffle plate 201b-2, a square block 201b-4 matched with the square through groove 201b-3, and a built-in block 201b-5 matched with the first connecting end 201a. The spring 201b-1 is used for connecting the baffle 201b-2 and the first matching plate 201b, and after the first connection end 201a is installed in the inner cavity of the first matching plate 201b, the baffle 201b-2 continuously extrudes the first connection end 201a to better fix the first connection end 201a.

Further, the built-in block 201b-5 includes a fitting projection 201b-51 fitted with the fitting groove 201a-2, and a groove 201b-52 fitted with the projection 201 a-1. The extension block 202 is provided with a plurality of groups, including a second connection end 202a arranged on the top thereof and a second matching plate 202b connected with the second connection end 202 a; the second connection terminal 202a is identical in structure to the first connection terminal 201a, and the second mating plate 202b is identical in structure to the first mating plate 201 b. The end 202a is connected with the cooperation of second cooperation board 202b through the second between the multiunit extension piece 202, and every extension piece 202 of group all can be connected with the cooperation of first end 201a, is convenient for adjust length, is applicable to multiple quilt survey device, has improved the practicality. The spring 201b-1, the baffle plate 201b-2, the square block 201b-4 and the built-in block 201b-5 are all arranged in the inner cavity of the first matching plate 201 b. The housing 100 further includes at least two sets of sockets 107 disposed at a top portion thereof. The housing can be plugged into the housing 100 through the plug 107 to close the housing 100.

When in use, the extension block 202 is increased or decreased according to the size of the device to be measured, and the first connecting end 201a and the second matching plate 202b are connected, so that the fixing component 200 is fixed on the device to be measured in a ring shape. The first adding mode is that when the adding block 202 is added, one end of the second connecting end 202a slides into the inner cavity of the first matching plate 201b through the sliding inlet 201b-6, when the top end bump of the second connecting end crosses the matching bump 201b-51, the second connecting end 202a is pushed into the cavity, then the adding block 202 is loosened, the extruded spring 201b-1 rebounds, the baffle plate 201b-2 is driven to extrude the second connecting end 202a, finally the second connecting end 202a is matched with the built-in block 201b-5, the adding block 202 is fixed in the second matching plate 202b, and the adding block 202 repeats the process. In a second adding mode, one end of a second connecting end 202a is jacked to the bottom of a first matching plate 201b through a sliding inlet 201b-6, at the moment, an L-shaped through groove 201a-3 and a square block 201b-4 are located on the same straight line, the second connecting end 202a is pushed into the cavity, the square block 201b-4 enters the L-shaped through groove 201a-3, when the L-shaped through groove 201a-3 and the square block 201b-4 are pushed into the end face of the cavity, an lengthening block 202 is loosened, at the moment, an extruded spring 201b-1 rebounds to drive a baffle 201b-2 to extrude the second connecting end 202a, and finally, the L-shaped through groove 201a-3 is clamped with the square block 201b-4, so that the lengthening block is fixed. Can adjust the elasticity degree of fixed subassembly 200 through the second joint mode, the temperature measuring device of being convenient for and the laminating of being surveyed the device improve the measuring degree of accuracy.

In sum, the length can be adjusted by additionally arranging the plurality of groups of lengthening blocks 202, so that different tested devices are met, and the practicability of the temperature sensor is improved. Each group of the elongated blocks 202 can be matched with the connecting piece 201, so that the shell 100 is fixed, the installation is convenient, the disassembly is rapid, and the time is saved. Through two kinds of block modes, adjust fixed subassembly 200's elasticity, be favorable to temperature measuring device and the laminating of being surveyed the device, effectual measurement accuracy that has improved.

Example 2

Referring to fig. 1 and 2, a second embodiment of the present invention, which is different from the first embodiment, is: the device also comprises a wireless temperature measuring module 102, a microprocessor module 103 and a wireless transmitting module 104. In the last embodiment, a wireless temperature sensor for monitoring electric power temperature includes casing 100 and fixed subassembly 200, fixed subassembly 200 sets up in the bottom of casing 100, and fixed subassembly 100 includes connecting piece 201 and extension piece 202, but connecting piece 201 itself front and back end connection realizes fixedly, and realizes can install extension piece 202 additional under the prerequisite fixed to the casing through connecting piece 201 and realize the regulation to length to satisfy the fixed demand of different devices under test.

Specifically, the housing 100, which has an accommodating space M formed therein, includes a mounting opening 101 disposed at the bottom of the housing 100, and the mounting opening 101 is disposed to be connected to the fixing component 200, so as to fix the sensor to the device to be tested.

The fixing assembly 200, which is disposed in the mounting opening 101 and has two ends extending out of the mounting opening 101, includes a connecting member 201 disposed at one end of the housing 100 and an elongated block 202 engaged with the connecting member 201. Through connecting piece 201 end to end, can fix the sensor on the device under test, extension piece 202 can set up to the multiunit according to the device under test of difference, and every group extension piece 202 all can be connected with connecting piece 201 one end, according to the device under test, dismantles or increases the extension piece, realizes the regulation to length to simple to operate, convenient to detach practices thrift a large amount of time.

Further, the connection member 201 includes a first connection end 201a disposed at one end thereof, a first mating plate 201b disposed at the other end thereof, and a mounting plate 201c connected to the first connection end 201a and the first mating plate 201 b. The first connection end 201a comprises a bump 201a-1 arranged at the top of the first connection end, a matching groove 201a-2 arranged at the bottom of the bump 201a-1, and an L-shaped through groove 201a-3 arranged in the middle of the bump 201 a-1; the first mating plate 201b comprises a spring 201b-1 arranged at the top thereof, a baffle 201b-2 connected with the spring 201b-1, a square through groove 201b-3 arranged on the baffle 201b-2, a square block 201b-4 mated with the square through groove 201b-3, and a built-in block 201b-5 mated with the first connecting end 201a. The spring 201b-1 is used for connecting the baffle 201b-2 and the first matching board 201b, and after the first connection end 201a is installed in the inner cavity of the first matching board 201b, the first connection end 201a is continuously extruded by the baffle 201b-2, so that the first connection end 201a is better fixed.

Further, the built-in block 201b-5 includes a fitting projection 201b-51 fitted with the fitting groove 201a-2, and a groove 201b-52 fitted with the projection 201 a-1. The lengthening block 202 is provided with a plurality of groups, including a second connecting end 202a arranged on the top thereof, and a second matching plate 202b connected with the second connecting end 202 a; the second connection terminal 202a is identical in structure to the first connection terminal 201a, and the second mating plate 202b is identical in structure to the first mating plate 201 b. End 202a is connected with the cooperation of second cooperation board 202b through the second between the multiunit extension piece 202, and every group extension piece 202 all can be connected with the cooperation of first end 201a, is convenient for adjust length, is applicable to multiple quilt survey device, has improved the practicality. The spring 201b-1, the baffle plate 201b-2, the square block 201b-4 and the built-in block 201b-5 are all arranged in the inner cavity of the first matching plate 201 b. The housing 100 further includes at least two sets of sockets 107 disposed at a top portion thereof. The housing can be plugged into the housing 100 through the plug 107 to close the housing 100.

Preferably, the housing 100 further includes a wireless temperature measuring module 102, a microprocessor module 103 and a wireless transmitting module 104 disposed in the accommodating space M. The wireless temperature measuring module 102 is connected with the microprocessor module 103, and the microprocessor module 103 is connected with the wireless transmitting module 104. The housing 100 also includes a temperature probe 105 connected to the wireless temperature module 102. The wireless temperature measurement module adopts a high-precision digital temperature sensor, particularly adopts a American DALLAS high-precision digital temperature sensor, and the series of sensors adopt measures such as full sealing, shielding grounding, equipotential principle, high-voltage absorption isolation and the like in design and manufacturing process, so that the safety, stability and high precision of data can be ensured. In this embodiment, the lower box body is provided with an opening, and a temperature probe 105 of the temperature sensor extends out of the shell 100 through the opening, so that the measuring end is attached to the point to be measured when the temperature measuring device is used.

When in use, the extension block 202 is increased or decreased according to the size of the device to be measured, and the first connecting end 201a and the second matching plate 202b are connected, so that the fixing component 200 is fixed on the device to be measured in a ring shape. The first adding mode is that when the adding block 202 is added, one end of the second connecting end 202a slides into the inner cavity of the first matching plate 201b through the sliding inlet 201b-6, when the top end bump of the second connecting end crosses the matching bump 201b-51, the second connecting end 202a is pushed into the cavity, then the adding block 202 is loosened, the extruded spring 201b-1 rebounds, the baffle plate 201b-2 is driven to extrude the second connecting end 202a, finally the second connecting end 202a is matched with the built-in block 201b-5, the adding block 202 is fixed in the second matching plate 202b, and the adding block 202 repeats the process. In a second adding mode, one end of a second connecting end 202a is jacked to the bottom of a first matching plate 201b through a sliding inlet 201b-6, at the moment, an L-shaped through groove 201a-3 and a square block 201b-4 are located on the same straight line, the second connecting end 202a is pushed into the containing cavity, the square block 201b-4 enters the L-shaped through groove 201a-3, when the second connecting end is pushed into the end face of the containing cavity, an lengthening block 202 is loosened, at the moment, an extruded spring 201b-1 rebounds, a baffle 201b-2 is driven to extrude the second connecting end 202a, and finally the L-shaped through groove 201a-3 is clamped with the square block 201b-4 to achieve fixing of the lengthening block. Can adjust the elasticity degree of fixed subassembly 200 through the second joint mode, the temperature measuring device of being convenient for and the laminating of being surveyed the device improve the measuring degree of accuracy.

In summary, the plurality of sets of elongated blocks 202 are connected to each other, the elongated blocks 202 are connected to the connecting member 201, and the fixing assembly 200 is connected to the housing 100. The length can be adjusted by additionally arranging the multiple groups of lengthening blocks 202, different tested devices are met, and the practicability of the temperature sensor is improved. Each group of the elongated blocks 202 can be matched with the connecting piece 201, so that the shell 100 is fixed, the installation is convenient, the disassembly is rapid, and the time is saved. Through two kinds of block modes, adjust fixed subassembly 200's elasticity, be favorable to temperature measuring device and the laminating of being surveyed the device, effectual measurement accuracy that has improved. The functions of measurement and wireless communication are realized through the wireless temperature measurement module 103, the microprocessor module 104 and the wireless transmission module 105, and the practicability of the device is enhanced. .

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (5)

1. A wireless temperature sensor for power temperature monitoring, characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

a housing (100) which forms an accommodating space (M) therein and comprises a mounting opening (101) arranged at the bottom of the housing (100); and the number of the first and second groups,

the fixing assembly (200) is arranged in the mounting opening (101), two ends of the fixing assembly extend out of the mounting opening (101), and the fixing assembly comprises a connecting piece (201) arranged at one end of the shell (100) and an elongated block (202) matched with the connecting piece (201);

the connecting piece (201) comprises a first connecting end (201 a) arranged at one end of the connecting piece, a first matching plate (201 b) arranged at the other end of the connecting piece, and a mounting plate (201 c) connected with the first connecting end (201 a) and the first matching plate (201 b);

the first connecting end (201 a) comprises a lug (201 a-1) arranged at the top of the first connecting end, a matching groove (201 a-2) arranged at the bottom of the lug (201 a-1), and an L-shaped through groove (201 a-3) arranged in the middle of the lug (201 a-1); the first matching plate (201 b) comprises a spring (201 b-1) arranged at the top of the first matching plate, a baffle (201 b-2) connected with the spring (201 b-1), a square through groove (201 b-3) arranged on the baffle (201 b-2), a square block (201 b-4) matched with the square through groove (201 b-3), and a built-in block (201 b-5) matched with the first connecting end (201 a);

the built-in block (201 b-5) comprises a matching lug (201 b-51) matched with the matching groove (201 a-2), and a groove (201 b-52) matched with the lug (201 a-1);

the lengthening blocks (202) are provided with a plurality of groups, and comprise second connecting end heads (202 a) arranged at the tops of the lengthening blocks and second matching plates (202 b) connected with the second connecting end heads (202 a); the second connecting end (202 a) is consistent with the first connecting end (201 a), and the second matching plate (202 b) is consistent with the first matching plate (201 b);

the spring (201 b-1), the baffle plate (201 b-2), the square block (201 b-4) and the built-in block (201 b-5) are all arranged in the inner cavity of the first matching plate (201 b).

2. The wireless temperature sensor for power temperature monitoring of claim 1, wherein: the shell (100) further comprises a wireless temperature measuring module (102), a microprocessor module (103) and a wireless transmitting module (104) which are arranged in the accommodating space (M).

3. The wireless temperature sensor for power temperature monitoring of claim 2, wherein: the wireless temperature measuring module (102) is connected with the microprocessor module (103), and the microprocessor module (103) is connected with the wireless transmitting module (104).

4. The wireless temperature sensor for power temperature monitoring of claim 3, wherein: the shell (100) further comprises a temperature measuring probe (105) connected with the wireless temperature measuring module (102).

5. The wireless temperature sensor for power temperature monitoring of claim 4, wherein: the shell (100) further comprises inserting ports (107) arranged at the top of the shell, and at least two groups of inserting ports (107) are arranged.

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