CN218673927U - Temperature monitoring device of pump - Google Patents

Abstract

The utility model discloses a temperature monitoring device of a pump, which has the key points of the technical proposal that the temperature monitoring device comprises an infrared temperature measuring device, a mounting rack and a monitoring host; the mounting rack comprises a first slide rail, a second slide rail and two supporting legs; the two supporting legs are hinged together, the bottom ends of the two supporting legs are in sliding connection with the second sliding rail and can be fixed on the second sliding rail, and the top ends of the two supporting legs are in sliding connection with the first sliding rail and can be fixed on the first sliding rail; the infrared temperature measuring devices are arranged in a plurality and are in sliding connection with the first sliding rail and can be fixed on the first sliding rail; all infrared temperature measurement devices are connected with a monitoring host, and the monitoring host comprises an alarm. The utility model provides a pump temperature monitoring device of easy adjustment of monitoring site to grasp the running state of pump in real time, guarantee that post staff can in time respond to the sudden failure of pump, prevent the emergence of great production accident, reduce post staff's working strength simultaneously.

Description

Temperature monitoring device of pump

Technical Field

The utility model relates to a temperature detection field of pump, more specifically the saying so, it relates to a temperature monitoring device of pump.

Background

At present, oil products are pressurized by a multi-purpose pump in the oil field production process. However, the service life discreteness of the pump is very large, some pumps can still normally operate after reaching the design life, and some pumps can break down when not reaching the design life for various reasons, so that post staff is required to timely know the failure of the pump and make a response to ensure the normal operation of the pump. Because the pump belongs to rotary machinery, the temperature of the pump body can relatively directly reflect the running state of the pump in the running process of the pump, and therefore the temperature of the pump body can be monitored to directly judge whether the running state of the pump is normal or not. In the prior art, manual detection is adopted for detecting the temperature of the pump, namely, a worker holds a temperature measuring gun to measure the temperature of the pump body.

Because of the large demand on the pumps at the production site, it is often necessary to run multiple pumps simultaneously. Because some old pumps have long working time, the temperature of the pump body has already obviously increased, the pumps are likely to lose efficacy at any time, and post staff are required to carry out frequent manual temperature measurement on a plurality of old pumps so as to detect the working state of the pumps. Because the size and the model of the new pump are not necessarily the same as those of the old pump, the positions of the temperature measuring parts of the old pump and the new pump are not necessarily the same. Although the manual temperature measurement can realize the measurement of temperature measurement parts at different positions, intensive and frequent measurement can also increase the working strength of post workers, and the manual temperature measurement method is discontinuous in the monitoring of the pump state, so that the post workers can not respond timely in the case of emergency of sudden failure of the pump, and large production accidents are easily caused.

Based on above-mentioned reason, how to develop the pump temperature monitoring devices that a monitoring point easily adjusted to real-time supervision pump body temperature masters the running state of pump in real time, guarantees that post staff can in time respond to the sudden failure of pump, prevents the emergence of great production accident, reduces post staff's working strength simultaneously, has become the problem that awaits a urgent need to solve among the oil field production operation.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a temperature monitoring device of pump, its change through providing two supporting leg angle sizes in the mounting bracket, and the change of infrared temperature measuring device position on first slide rail realizes monitoring the adjustment of site on vertical and horizontal direction, the utility model discloses can replace the manual work to realize the long-time detection of pump body temperature, make post staff can master the running state of pump in real time, in time respond to the sudden failure of pump, prevent the emergence of great production accident, still reduced post staff's working strength simultaneously.

In order to achieve the above purpose, the utility model provides a following technical scheme: a temperature monitoring device of a pump comprises an infrared temperature measuring device, a mounting rack and a monitoring host; the mounting rack comprises a first slide rail, a second slide rail and two supporting legs; the two supporting legs are crossed and hinged together to form an X shape, the bottom ends of the two supporting legs are in sliding connection with the second sliding rail and can be fixed on the second sliding rail, and the top ends of the two supporting legs are in sliding connection with the first sliding rail and can be fixed on the first sliding rail; the infrared temperature measuring devices are arranged in a plurality and all the infrared temperature measuring devices are connected with the first slide rail in a sliding way and can be fixed on the first slide rail; all infrared temperature measurement device all are connected with the monitoring host computer, the monitoring host computer contains the alarm.

The utility model discloses further set up to: the mounting rack also comprises first mounting assemblies, each infrared temperature measuring device corresponds to one first mounting assembly, and each first mounting assembly comprises a first sliding block and a supporting rod; the first sliding block is connected with the first sliding rail in a sliding way and can be fixed on the first sliding rail; one end of the supporting rod is fixedly connected with the corresponding infrared temperature measuring device, the other end of the supporting rod is rotatably connected with the first sliding block, and the supporting rod can be fixed on the first sliding block.

The utility model discloses further set up to: the first mounting assembly further comprises a first positioning pin, and the first sliding block is provided with a first positioning hole matched with the first positioning pin; and second positioning holes matched with the first positioning pins are arranged at different positions of the first slide rail along the length direction of the first slide rail.

The utility model discloses further set up to: a first sliding groove for accommodating a first sliding block is formed in the first sliding rail and is a T-shaped groove, and the first sliding block is T-shaped.

The utility model discloses further set up to: the mounting rack also comprises second mounting assemblies, and one second mounting assembly is mounted at the end part of each supporting leg; the second mounting assembly comprises a second sliding block and a second positioning pin, the second sliding block is hinged with the end part of the corresponding supporting leg, and a third positioning hole matched with the second positioning pin is formed in the second sliding block; and fourth positioning holes matched with the second positioning pins are formed in different positions of the second slide rail along the length direction of the second slide rail, and fourth positioning holes matched with the second positioning pins are also formed in different positions of the first slide rail along the length direction of the first slide rail.

The utility model discloses further set up to: the first slide rail and the second slide rail are both provided with second slide grooves for accommodating the second slide blocks, the second slide grooves are T-shaped grooves, and the second slide blocks are T-shaped.

The utility model discloses further set up to: the alarm is at least one of a sound alarm and a light alarm.

The utility model discloses further set up to: the monitoring host further comprises a display.

The utility model discloses further set up to: the monitoring host further comprises a communication module, and a wired transmission unit and a wireless transmission unit are arranged in the communication module.

The utility model discloses further set up to: the monitoring host further comprises an ambient temperature sensor.

To sum up, the utility model discloses compare in prior art and have following beneficial effect: the utility model discloses a change of two supporting leg angle sizes in the mounting bracket and the change of infrared temperature measuring device position on first slide rail realize monitoring the adjustment of site on vertical and horizontal direction. The utility model discloses can replace the manual work to realize the long-time detection of pump body temperature, make post staff can master the running state of pump in real time, in time respond to the sudden failure of pump, prevent the emergence of great production accident, still reduce post staff's working strength simultaneously.

Drawings

FIG. 1 is a front view of the present embodiment;

FIG. 2 is a top view of the present embodiment;

FIG. 3 is a left side view of the present embodiment;

fig. 4 is an electrical schematic diagram of the present embodiment.

In the figure: 1. an infrared temperature measuring device; 2. a mounting frame; 21. a first slide rail; 211. a first chute; 212. a second positioning hole; 22. a second slide rail; 221. a second chute; 222. a fourth positioning hole; 23. supporting legs; 24. a support shaft; 25. a first mounting assembly; 251. a first slider; 252. a support bar; 253. a hand wheel; 254. a first positioning pin; 26. a second mounting assembly; 261. a second slider; 262. a second positioning pin; 3. a data transmission cable; 4. monitoring the host; 41. an audible alarm; 42. an optical alarm; 43. a single chip microcomputer; 44. an A/D converter; 45. a control panel; 46. a display; 47. a communication module; 48. an ambient temperature sensor; 49. and rectifying the power supply.

Detailed Description

The technical solution of the present invention will be described clearly with reference to the accompanying drawings, and it is obvious that the described embodiments are not all embodiments of the present invention, and all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that the terms "center", "upper", "lower", "horizontal", "left", "right", "front", "rear", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

As shown in fig. 1-3, for a preferred embodiment of the present invention, a basic structure of a temperature monitoring device for a pump includes an infrared temperature measuring device 1, a mounting frame 2, a data transmission cable 3 and a monitoring host 4; the mounting rack 2 comprises a first slide rail 21, a second slide rail 22, two supporting legs 23 and a supporting rotating shaft 24; the two support legs 23 are crossed and hinged together through a support rotating shaft 24 to form an X shape. The bottom ends of the two supporting legs 23 are connected with the second slide rails 22 in a sliding manner and can be fixed on the second slide rails 22, and the top ends of the two supporting legs 23 are connected with the first slide rails 21 in a sliding manner and can be fixed on the first slide rails 21; infrared temperature measurement device 1 sets up a plurality ofly, and all infrared temperature measurement device 1 all with first slide rail 21 sliding connection and homoenergetic are fixed on first slide rail 21, and infrared temperature measurement device 1 sets up threely in this embodiment. All infrared temperature measurement device 1 all is connected with monitoring host 4 through data transmission cable 3, monitoring host 4 contains the alarm. The temperature detected by any infrared temperature measuring device 1 exceeds the temperature range of normal operation of the pump, and an alarm is triggered to send out an alarm signal.

This embodiment passes through the change of two supporting legs 23 angle sizes in the mounting bracket 2, and the change of infrared temperature measuring device 1 position on first slide rail 21, realize the adjustment of monitoring site on vertical and horizontal direction, make this embodiment can replace the manual work to realize the long-time detection of pump body temperature, so that post staff can master the running state of pump in real time, in time respond to the sudden failure of pump, prevent the emergence of great production accident, post staff's working strength has still been reduced simultaneously.

In this embodiment, the mounting frame 2 further includes first mounting assemblies 25, each infrared temperature measuring device 1 corresponds to one first mounting assembly 25, and each first mounting assembly 25 includes a first slider 251 and a supporting rod 252; the first sliding block 251 is connected with the first sliding rail 21 in a sliding way and can be fixed on the first sliding rail 21; one end of the supporting rod 252 is fixedly connected to the corresponding infrared temperature measuring device 1, and the other end is rotatably connected to the first slider 251, and the supporting rod 252 can be fixed to the first slider 251. The post staff can adjust the elevation angle of the infrared temperature measuring device 1 by changing the included angle between the supporting rod 252 and the first sliding block 251.

The first mounting assembly 25 in this embodiment further comprises a bolt and a nut, and the bolt is connected with the nut after passing through the first slider 251 and the support rod 252. Specifically, the first mounting assembly 25 further includes a hand wheel 253, and the hand wheel is fixedly connected with a bolt head of the bolt.

Specifically, a first sliding groove 211 for accommodating a first sliding block 251 is formed in the first sliding rail 21, the first sliding groove 211 is a T-shaped groove, and the first sliding block 251 is T-shaped. The first slider 251 of the T-shape will only leave the T-shape along the length of the first slide rail 21, limited by the walls of the T-shape groove. The first sliding groove 211 is located on the top surface of the first sliding rail 21 in this embodiment.

Specifically, the first mounting assembly 25 further includes a first positioning pin 254, and the first slider 251 is provided with a first positioning hole matched with the first positioning pin 254; the first slide rail 21 is provided with second positioning holes 212 at different positions along the length direction thereof for matching with the first positioning pins 254. In this embodiment, two sets of the second positioning holes 212 are disposed, and the two sets of the second positioning holes 212 are respectively located on two groove walls at the top of the first sliding groove 211. All the second positioning holes 212 of the same group are arranged along the length direction of the first slide rail 21. Two first positioning holes are formed in the first slider 251 and two first positioning pins 254 are formed in the first slider 251 corresponding to the two sets of positioning holes. Through the cooperation of the first positioning pin 254, the first positioning hole and the second positioning hole 212 at different positions, the first slider 251 can be fixed at different positions of the first slide rail 21, thereby realizing the position change of the infrared temperature measuring device 1 in the length direction of the first slide rail 21.

In the embodiment, the mounting frame 2 further comprises second mounting assemblies 26, and one second mounting assembly 26 is mounted at the end of each supporting leg 23; the second mounting assembly 26 comprises a second sliding block 261 and a second positioning pin 262, the second sliding block 261 is hinged to the end portion of the corresponding supporting leg 23, a second sliding groove 221 for accommodating the second sliding block 261 is formed in each of the first sliding rail 21 and the second sliding rail 22, and the second sliding groove 221 is a T-shaped groove. The second slider 261 of the T-shape will only be able to leave the T-shape along the length of the second slide 22, limited by the walls of the T-shape slot. In this embodiment, the two second sliding slots 221 are respectively located on the bottom surface of the first sliding rail 21 and the top surface of the second sliding rail 22.

Specifically, the second slider 261 is provided with a third positioning hole matched with the second positioning pin 262; the second slide rail 22 is provided with a fourth positioning hole 222 matching with the second positioning pin 262 at different positions along the length direction thereof, and the first slide rail 21 is also provided with a fourth positioning hole 222 matching with the second positioning pin 262 at different positions along the length direction thereof. In this embodiment, four sets of the fourth positioning holes 222 are respectively disposed on the four groove walls of the two second sliding grooves 221, which are close to each other. All the fourth positioning holes 222 in the same group on the first slide rail 21 are arranged along the length direction of the first slide rail 21, and all the fourth positioning holes 222 in the same group on the second slide rail 22 are arranged along the length direction of the second slide rail 22. Two third positioning holes are formed in the second slider 261, and two second positioning pins 262 are also formed in the second slider 261. Through the cooperation of the second positioning pin 262, the third positioning hole and the fourth positioning hole 222 at different positions, the second slider 261 can be fixed at different positions of the first slide rail 21 and the second slide rail 22, so that the angle between the two support legs 23 can be changed, and the position change of the infrared temperature measuring device 1 in the vertical direction can be realized.

Specifically, in this embodiment, the second positioning pin 262 is a bolt, the hole walls of all the third positioning holes are provided with internal threads, and the second slider 261 is in threaded connection with the second positioning pin 262.

Specifically, the alarm is at least one of an audible alarm 41 and a light alarm 42. In the present embodiment, two alarms are provided, namely, an audible alarm 41 and a light alarm 42.

As shown in fig. 4, the monitoring host 4 further includes a single chip microcomputer 43 and an a/D converter 44, where the a/D converter 44 is configured to receive analog signals sent by all the infrared temperature measuring devices 1, convert the analog signals into digital signals, and send the digital signals to the single chip microcomputer 43; the single chip microcomputer 43 is used for analyzing information in the digital signal, and once the infrared temperature measuring device 1 detects temperature abnormality, the single chip microcomputer 43 controls the sound alarm 41 and the light alarm 42 to send out sound alarm signals and light alarm signals so as to inform post staff of detecting that the pump is in an abnormal working state.

Specifically, the monitoring host 4 further includes a control panel 45 and a display 46, and the control panel 45 and the display 46 are both connected to the single chip microcomputer 43. The control board 45 is used for manually adjusting parameter settings, changing the standard for judging whether the temperature is abnormal in the single chip microcomputer 43, and controlling the on-off of the single infrared temperature measuring device 1. The display 46 is used for displaying temperature values detected by all the infrared temperature measuring devices 1 and displaying the running states (normal and abnormal) of the corresponding pumps.

Specifically, the monitoring host 4 further includes a communication module 47, and a wired transmission unit and a wireless transmission unit are disposed in the communication module 47, so that the detected data and the analysis result of the single chip microcomputer 43 are transmitted to other devices through a wired transmission or wireless transmission means, and are reserved as records, so as to analyze the operation state of the pump at a later stage.

Specifically, the monitoring host 4 further comprises an ambient temperature sensor 48, the ambient temperature sensor 48 is used for monitoring the ambient temperature inside the host 4, and sending ambient temperature data to the single chip microcomputer 43, and once the ambient temperature is too high, the single chip microcomputer 43 drives the sound alarm 41 and the light alarm 42 to send out sound alarm signals and light alarm signals to inform post staff of abnormal temperature and to adjust the post staff in time. The ambient temperature sensor 48 can prevent the monitoring host 4 from exploding due to the over-high temperature of the internal electrical elements, avoid the possibility of explosion of the monitoring host 4 in the flammable and explosive environment filled with oil products, and improve the safety of the embodiment. The ambient temperature sensor 48 is connected to the a/D converter 44 in this embodiment.

Specifically, the monitoring host 4 further includes a rectifying power supply 49, which is used for converting ac power into dc power and transmitting the dc power to the a/D converter 44, the single chip microcomputer 43, the audible alarm 41, the optical alarm 42, and the communication module 47. The rectified power supply 49 in the present embodiment is suitable for an ac environment of 220V.

Specifically, in the present embodiment, the monitoring host 4 is fixed on the second slide rail 22 by bolts and nuts.

In summary, the height of the present embodiment can be preliminarily determined by the X-shaped structure formed by the two support legs 23 according to the size and model of the monitored pump during installation, and then the left and right positions of the first slide block 251 can be adjusted. After the initial position of the infrared temperature measuring device 1 is confirmed, the pitching angle of the infrared temperature measuring device 1 can be finely adjusted according to the hand wheel 253, so that the measuring point can be flexibly selected, and a more accurate measuring result can be obtained. The post staff can master the running state of the pump in real time through the embodiment, respond to the sudden failure of the pump in time, and prevent the occurrence of large production accidents. Meanwhile, manual temperature measurement is not needed, and the working strength of post staff is reduced.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A temperature monitoring device of a pump is characterized in that: the device comprises an infrared temperature measuring device (1), a mounting rack (2) and a monitoring host (4);

the mounting rack (2) comprises a first slide rail (21), a second slide rail (22) and two supporting legs (23); the two supporting legs (23) are crossed and hinged together to form an X shape, the bottom ends of the two supporting legs (23) are in sliding connection with the second sliding rail (22) and can be fixed on the second sliding rail (22), and the top ends of the two supporting legs (23) are in sliding connection with the first sliding rail (21) and can be fixed on the first sliding rail (21); the infrared temperature measuring devices (1) are arranged in a plurality, and all the infrared temperature measuring devices (1) are connected with the first sliding rail (21) in a sliding manner and can be fixed on the first sliding rail (21); all infrared temperature measurement device (1) all are connected with monitoring host computer (4), monitoring host computer (4) contain the alarm.

2. A temperature monitoring device for a pump according to claim 1, wherein: the mounting frame (2) further comprises first mounting assemblies (25), each infrared temperature measuring device (1) corresponds to one first mounting assembly (25), and each first mounting assembly (25) comprises a first sliding block (251) and a supporting rod (252); the first sliding block (251) is connected with the first sliding rail (21) in a sliding way and can be fixed on the first sliding rail (21); one end of the supporting rod (252) is fixedly connected with the corresponding infrared temperature measuring device (1), the other end of the supporting rod is rotatably connected with the first sliding block (251), and the supporting rod (252) can be fixed on the first sliding block (251).

3. A temperature monitoring device for a pump according to claim 2, wherein: the first mounting assembly (25) further comprises a first positioning pin (254), and a first positioning hole matched with the first positioning pin (254) is formed in the first sliding block (251); and second positioning holes (212) matched with the first positioning pins (254) are formed in different positions of the first slide rail (21) along the length direction of the first slide rail.

4. A temperature monitoring device for a pump according to claim 2, wherein: a first sliding groove (211) for accommodating a first sliding block (251) is formed in the first sliding rail (21), the first sliding groove (211) is a T-shaped groove, and the first sliding block (251) is T-shaped.

5. A temperature monitoring device for a pump according to any one of claims 1 to 4, wherein: the mounting rack (2) further comprises second mounting assemblies (26), one second mounting assembly (26) is mounted at the end of each supporting leg (23); the second mounting assembly (26) comprises a second sliding block (261) and a second positioning pin (262), the second sliding block (261) is hinged with the end part of the corresponding supporting leg (23), and a third positioning hole matched with the second positioning pin (262) is formed in the second sliding block (261); and fourth positioning holes (222) matched with the second positioning pins (262) are formed in different positions of the second slide rail (22) along the length direction of the second slide rail, and fourth positioning holes (222) matched with the second positioning pins (262) are also formed in different positions of the first slide rail (21) along the length direction of the first slide rail.

6. The apparatus for monitoring the temperature of a pump according to claim 5, wherein: all offer second spout (221) that hold second slider (261) on first slide rail (21) and second slide rail (22), second spout (221) are T type groove, second slider (261) are the T type.

7. A temperature monitoring device for a pump according to claim 1, wherein: the alarm is at least one of an acoustic alarm (41) and a light alarm (42).

8. A temperature monitoring device for a pump according to claim 1, wherein: the monitoring host (4) further comprises a display (46).

9. A temperature monitoring device for a pump according to claim 1, wherein: the monitoring host (4) further comprises a communication module (47), and a wired transmission unit and a wireless transmission unit are arranged in the communication module (47).

10. A temperature monitoring device for a pump according to claim 1, wherein: the monitoring host (4) further comprises an ambient temperature sensor (48).

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