CN219757481U - Gas flowmeter supervisory equipment - Google Patents

Abstract

The utility model relates to the technical field of gas monitoring equipment, in particular to gas flowmeter monitoring equipment, which comprises a shell, a monitoring equipment body and a protection mechanism, wherein the protection mechanism comprises a driving assembly, a gear, two racks, two blocks and two door bodies, the shell is positioned on the monitoring equipment body and the protection mechanism to provide mounting conditions, after the monitoring equipment body and the flowmeter are mounted and debugged, the driving assembly is started, the driving assembly works to drive the gear to rotate, the gear drives the two racks to move, the two racks drive the two blocks to slide in the shell, the two blocks drive the two door bodies to mutually approach each other until the two door bodies move to a preset position, and the shell is sealed, so that the monitoring equipment body in the shell can be protected, and the problem that overhead equipment is possibly damaged when the monitoring equipment is impacted by external force is solved.

Description

Gas flowmeter supervisory equipment

Technical Field

The utility model relates to the technical field of gas monitoring equipment, in particular to gas flowmeter monitoring equipment.

Background

The gas monitoring system is used for monitoring data information of each gas meter flowmeter, data are summarized into the monitoring server through the radio station, data processing and analysis are carried out, a user can conveniently collect and analyze flow data of the gas meter flowmeter, at present, data displayed on the gas meter flowmeter only have current flow information, conventional data cannot be summarized and inquired, and the conventional data cannot be timely fed back to field staff when faults occur, so that gas use conditions cannot be summarized and analyzed, fault information cannot be timely processed, the gas monitoring system is inconvenient to use, information cannot be timely reflected, and use requirements cannot be met.

Currently, the prior art (CN 202614339U) discloses a monitoring system for flow status data of a gas meter, which is characterized in that: the monitoring system comprises a plurality of gas meter flowmeters, data acquisition equipment, a radio station and a monitoring server of a central control room, wherein the gas meter flowmeters are connected with the data acquisition equipment, the data acquisition equipment is in wireless connection with the radio station, the radio station sends signals to the monitoring server of the central control room, and the monitoring server is connected with the radio station through a serial port converter. The beneficial effects are that: by the application of the system, the data can be analyzed timely and effectively, so that the production is safer and more humanized, and resources are used more reasonably. And the acquired data enter a monitoring server to store the data. The instantaneous flow, temperature, pressure, total flow, fault information and the like of the gas meter flowmeter contained in the data are displayed on a monitoring computer, and audible and visual alarm is carried out on the values exceeding the range and the fault information of the gas meter flowmeter, so that staff is reminded of timely processing the problems.

By adopting the mode, the monitoring equipment is arranged on one side of the gas flowmeter, and when the monitoring equipment is impacted by external force, the damage to overhead equipment can be caused.

Disclosure of Invention

The utility model aims to provide a gas flowmeter monitoring device, which aims to solve the problem that overhead equipment is possibly damaged when the monitoring device is impacted by external force when the monitoring device is arranged on one side of a gas flowmeter.

In order to achieve the above purpose, the utility model provides a gas flowmeter monitoring device, which comprises a shell, a monitoring device body and a protection mechanism, wherein the protection mechanism comprises a driving assembly, a gear, two racks, two blocks and two door bodies;

the monitoring equipment body set up in the shell, drive assembly set up in the shell, the gear set up in one side of drive assembly, two the rack respectively with gear engagement, two the block respectively with two rack fixed connection, and respectively with shell sliding connection, all be located the rack with between the shell, two the door body respectively with two block fixed connection, and be located two one side of block respectively.

The driving assembly comprises a motor and a rotating shaft, wherein the motor is fixedly connected with the shell and is positioned on one side of the shell, and the rotating shaft is fixedly connected with the output end of the motor and is fixedly connected with the gear.

The protection mechanism further comprises two guide assemblies, and the two guide assemblies are respectively arranged between the shell and the two door bodies.

The guide assembly comprises a sliding rail and a sliding block, wherein the sliding rail is fixedly connected with the shell and is positioned in the shell, and the sliding block is in sliding connection with the sliding rail and is fixedly connected with the door body.

The gas flowmeter monitoring equipment further comprises two engaging plates, bolts and nuts, wherein the two engaging plates are respectively connected with the shell in a sliding mode and are respectively located at the bottom of the shell, the bolts penetrate through the two engaging plates, and the nuts are in threaded connection with the bolts and located around the bolts.

According to the gas flowmeter monitoring equipment, the shell is positioned on the monitoring equipment body and the protection mechanism, mounting conditions are provided, the flowmeter can be monitored through the monitoring equipment body, after the monitoring equipment body and the flowmeter are mounted and debugged, the driving assembly is started, the driving assembly works to drive the gear to rotate, the gear drives the two racks to move, the two racks drive the two blocks to slide in the shell, the two blocks drive the two doors to mutually approach, the monitoring equipment body in the shell can be protected until the two doors move to a preset position and the shell is closed, and therefore the problem that the overhead equipment is possibly damaged when the monitoring equipment is mounted on one side of the gas flowmeter and is impacted by external force is solved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic structural view of a gas flow meter monitoring apparatus according to a first embodiment of the present utility model.

Fig. 2 is a sectional view of a gas flow meter monitoring apparatus according to a first embodiment of the present utility model along a motor direction.

Fig. 3 is a sectional view of a gas flow meter monitoring apparatus according to a first embodiment of the present utility model along a door body direction.

Fig. 4 is a schematic structural view of a gas flow meter monitoring apparatus according to a first embodiment of the present utility model.

The device comprises a 101-shell, a 102-monitoring equipment body, a 103-protection mechanism, a 104-driving assembly, a 105-gear, a 106-rack, a 107-block body, a 108-door body, a 109-guiding assembly, a 110-slide rail, a 111-slide block, a 112-motor, a 113-rotating shaft, a 201-engagement plate, a 202-bolt and a 203-nut.

Detailed Description

The first embodiment of the utility model is as follows:

referring to fig. 1 to 3, fig. 1 is a schematic structural diagram of a gas flow meter monitoring device, fig. 2 is a sectional view of the gas flow meter monitoring device along a motor direction, and fig. 3 is a sectional view of the gas flow meter monitoring device along a door body direction.

The utility model provides a gas flowmeter monitoring device, which comprises a shell 101, a monitoring device body 102 and a protection mechanism 103, wherein the protection mechanism 103 comprises a driving assembly 104, a gear 105, two racks 106, two blocks 107, two door bodies 108 and two guide assemblies 109, the guide assemblies 109 comprise sliding rails 110 and sliding blocks 111, and the driving assembly 104 comprises a motor 112 and a rotating shaft 113. The problem that monitoring equipment is installed on one side of a gas flowmeter and possibly damaged by overhead equipment when the monitoring equipment is impacted by external force is solved through the scheme, and it can be understood that the scheme can be used in a scene of protecting the monitoring equipment body 102 and can also be used for solving the problem of unstable movement of the two door bodies 108.

For this embodiment, the monitoring device body 102 is disposed in the housing 101, the driving assembly 104 is disposed in the housing 101, the gear 105 is disposed on one side of the driving assembly 104, the two racks 106 are respectively meshed with the gear 105, the two blocks 107 are respectively fixedly connected with the two racks 106 and respectively slidingly connected with the housing 101, the two door bodies 108 are respectively fixedly connected with the two blocks 107 and respectively located on one side of the two blocks 107, and are respectively located between the racks 106 and the housing 101. The shell 101 is located the supervisory equipment body 102 with protection machanism 103 provides the installation condition, through supervisory equipment body 102 can monitor the flowmeter, drive assembly 104 work can drive gear 105 rotates, gear 105 rotates can drive two rack 106 removes, through two rack 106 can drive two block 107 slide in shell 101, through two block 107 can drive two door body 108 are close to each other or keep away from each other, two door body 108 remove can open shell 101 or seal shell 101.

The motor 112 is fixedly connected with the housing 101 and is located at one side of the housing 101, and the rotating shaft 113 is fixedly connected with the output end of the motor 112 and is fixedly connected with the gear 105. The motor 112 can drive the rotating shaft 113 to rotate forward or reverse, and the rotating shaft 113 can drive the gear 105 to rotate forward or reverse.

Next, two guide assemblies 109 are respectively disposed between the housing 101 and the two door bodies 108. The two door bodies 108 can be guided by the two guide assemblies 109, so that stability of the two door bodies 108 during movement is improved.

Meanwhile, the sliding rail 110 is fixedly connected with the housing 101 and is located in the housing 101, and the sliding block 111 is slidably connected with the sliding rail 110 and is fixedly connected with the door 108. The sliding rail 110 provides a mounting condition for the sliding block 111, when the door body 108 moves, the sliding block 111 is driven to slide on the sliding rail 110, the sliding block 111 guides the door body 108, and stability of the door body 108 during movement is improved.

After the installation and debugging of the monitoring equipment body 102 and the flowmeter are completed, the motor 112 is started, the motor 112 works to drive the rotating shaft 113 to rotate, the rotating shaft 113 drives the gear 105 to rotate, the gear 105 drives the two racks 106 to move, the two racks 106 drive the two blocks 107 to slide in the shell 101, the two blocks 107 drive the two door bodies 108 to be close to each other until the two door bodies 108 move to a preset position and the shell 101 is closed, the monitoring equipment body 102 in the shell 101 can be protected, and therefore the problem that overhead equipment is possibly damaged when the monitoring equipment is impacted by external force is solved when the monitoring equipment is installed on one side of the gas flowmeter.

The second embodiment of the utility model is as follows:

referring to fig. 4, fig. 4 is a schematic structural diagram of a monitoring device for a gas flow meter.

On the basis of the first embodiment, the gas flow meter monitoring device of the present utility model further comprises two engagement plates 201, a bolt 202 and a nut 203.

For the present embodiment, the two engaging plates 201 are slidably connected to the housing 101, and are located at the bottom of the housing 101, the bolt 202 penetrates through the two engaging plates 201, and the nut 203 is screwed to the bolt 202 and is located around the bolt 202. The housing 101 can be mounted at a predetermined position by the two engagement plates 201, and the two engagement plates 201 can be fixed by the bolts 202 and the nuts 203.

When the housing 101 needs to be mounted at a preset position, the two engaging plates 201 are slid, the distance between the two engaging plates 201 is slid to the preset position, the two engaging plates 201 are placed at the preset mounting position, the bolt 202 passes through the two engaging plates 201, the nut 203 is screwed on the bolt 202, the nut 203 is turned to the side close to the engaging plates 201 until the nut 203 contacts with the engaging plates 201, and the nut 203 is screwed, so that the two engaging plates 201 can be fixed, and the mounting of the housing 101 is completed.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present utility model, and it is not intended to limit the scope of the claims hereof, as persons of ordinary skill in the art will understand that all or part of the processes for practicing the embodiments described herein may be practiced with equivalent variations in the claims, which are within the scope of the utility model.

Claims (5)

1. The monitoring equipment for the gas flowmeter comprises a shell and a monitoring equipment body, wherein the monitoring equipment body is arranged in the shell,

the protection mechanism comprises a driving assembly, a gear, two racks, two blocks and two door bodies;

the driving assembly is arranged in the shell, the gear is arranged on one side of the driving assembly, the two racks are respectively meshed with the gear, the two blocks are respectively fixedly connected with the two racks and are respectively in sliding connection with the shell, the two blocks are respectively fixedly connected with the two blocks and are respectively positioned on one side of the two blocks, and the two door bodies are respectively positioned between the racks and the shell.

2. A gas flow meter monitoring device as set forth in claim 1, wherein,

the driving assembly comprises a motor and a rotating shaft, the motor is fixedly connected with the shell and is positioned on one side of the shell, and the rotating shaft is fixedly connected with the output end of the motor and is fixedly connected with the gear.

3. A gas flow meter monitoring device as set forth in claim 2, wherein,

the protection mechanism further comprises two guide assemblies, and the two guide assemblies are respectively arranged between the shell and the two door bodies.

4. A gas flow meter monitoring device as set forth in claim 3, wherein,

the guide assembly comprises a sliding rail and a sliding block, wherein the sliding rail is fixedly connected with the shell and is positioned in the shell, and the sliding block is in sliding connection with the sliding rail and is fixedly connected with the door body.

5. A gas flow meter monitoring device as set forth in claim 4, wherein,

the gas flowmeter monitoring equipment further comprises two engaging plates, bolts and nuts, wherein the two engaging plates are respectively connected with the shell in a sliding mode and are respectively located at the bottom of the shell, the bolts penetrate through the two engaging plates, and the nuts are in threaded connection with the bolts and located around the bolts.