CN216625379U - Central water supply monitoring management device - Google Patents

Abstract

The utility model provides a central water supply monitoring and managing device, which relates to the technical field of water supply monitoring and managing devices and comprises a supporting assembly and an adjusting mechanism, wherein a pipeline assembly is arranged on the supporting assembly, a pressure measuring assembly is arranged on the side of the pipeline assembly, the pipeline assembly is provided with the adjusting mechanism in a sleeved mode, and the adjusting mechanism comprises a valve body, a butterfly valve plate and a shaft sleeve; the utility model mainly utilizes a structure formed by two mutually vertical meshed gear pieces arranged on the outer side of an output end connected with a butterfly valve piece, and is matched with a hand-operated wheel penetrating through the outer side, so that the manual regulation can be realized, the effect of regulating the flow rate under the non-electric power condition is solved, and meanwhile, a motor of a pressure pump can play a role of reversely generating electric power when the self-regulation is not needed, so that the electric energy is stored, the temporary starting effect can be realized when the equipment is powered off, and the self-regulation effect can be realized when no worker is on the spot.

Description

Central water supply monitoring management device

Technical Field

The utility model relates to the technical field of water supply monitoring and management devices, in particular to a central water supply monitoring and management device.

Background

A water supply monitoring and management device, generally comprising: the pressure, flow rate of the water supply network, monitored by the consumer, generally includes: monitoring the flow and pressure of water supply for a water user; the IC card controls the valve to supply water or remotely controls the valve to supply water.

The utility model provides a central water supply monitoring management device, which solves the problems that the existing water supply monitoring management device loses the function of self detection and regulation and control and is difficult to ensure the water supply management and the like when power is cut off accidentally in the use process.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a central water supply monitoring and management device which is mainly formed by two mutually vertical meshing gear pieces arranged on the outer side of an output end connected with a butterfly valve piece, and is matched with a hand-operated wheel penetrating through the outer side to achieve the effect of manually adjusting, so that the flow and flow rate can be adjusted under the non-electric power condition.

In order to realize the purpose of the utility model, the utility model is realized by the following technical scheme: a central water supply monitoring and managing device comprises a supporting assembly and an adjusting mechanism, wherein a pipeline assembly is arranged on the supporting assembly, a pressure measuring assembly is arranged on the side of the pipeline assembly, and the pipeline assembly is provided with the adjusting mechanism in a sleeved mode;

adjustment mechanism includes valve body, butterfly valve block, axle sleeve, meshing gear train, first motor, sleeve pipe seat, hand wheel and signal piece, the valve body cup joints on the pipe assembly, the inside of valve body is provided with the butterfly valve block, just the top of butterfly valve block is provided with the axle sleeve that the bearing is connected, the top of axle sleeve is provided with the meshing gear train that the bearing is connected, just the meshing gear train is connected with the output of first motor, just the top of valve body is provided with the sleeve pipe seat, one side of sleeve pipe seat is provided with hand wheel, the top side of first motor is provided with the signal piece, one side pipe connection of valve body has pressure boost subassembly.

The valve body, the first motor and the central axis of the sleeve seat are positioned on the same straight line, the meshing gear set is of two groups of mutually meshed vertical gears, and the butterfly valve plate is of a butterfly structure.

The supporting assembly comprises a bottom plate and supporting pipe sleeves, and a plurality of groups of supporting pipe sleeves distributed in parallel are arranged above the bottom plate.

The improved pipeline assembly comprises a water inlet, a flange plate, a main pipe and a water outlet, wherein the main pipe is sleeved on the inner side of the supporting pipe sleeve, one end of the main pipe is connected with the water inlet through a flange plate bolt, and the other end of the main pipe is provided with the water outlet.

The pressure measuring assembly comprises a side pipe sleeve, a spring seat, a push rod, a piston and a sensor, the side pipe sleeve is arranged on one side of the main pipe, the spring seat is arranged at one end of the side pipe sleeve, the spring seat penetrates through the side pipe sleeve and is connected with the push rod, the piston is arranged at one end of the push rod, the sensor is arranged at one end of the spring seat, and the sensor is connected with the signal block through a signal line.

The improvement is that, the pressure boost subassembly includes the pressurization pump body, bearing housing, second motor, rotary rod and turbine blade, the pressurization pump body has the valve body through the pipe connection, the inboard of the pressurization pump body is provided with the bearing housing, the bearing housing is connected with the output of second motor, the output of second motor runs through the bearing housing is connected with the rotary rod, just the outside of rotary rod is provided with the turbine blade, the second motor pass through the wire with the signal block is connected.

The utility model has the beneficial effects that:

the utility model mainly utilizes a structure formed by two mutually vertical meshed gear pieces arranged on the outer side of an output end connected with a butterfly valve piece, and is matched with a hand-operated wheel penetrating through the outer side, so that the manual regulation can be realized, the effect of regulating the flow rate under the non-electric power condition is solved, and meanwhile, a motor of a pressure pump can play a role of reversely generating electric power when the self-regulation is not needed, so that the electric energy is stored, the temporary starting effect can be realized when the equipment is powered off, and the self-regulation effect can be realized when no worker is on the spot.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic side-view perspective of the present invention;

FIG. 3 is a schematic perspective view of the load cell assembly of the present invention;

FIG. 4 is a schematic perspective view of an adjustment mechanism according to the present invention;

fig. 5 is a schematic perspective view of the supercharging assembly of the present invention.

Wherein: 1. a support assembly; 101. a base plate; 102. a support sleeve; 2. a conduit assembly; 201. a water inlet; 202. a flange plate; 203. a main body tube; 204. a water outlet; 3. a pressure measuring assembly; 301. a side pipe sleeve; 302. a spring seat; 303. a push rod; 304. a piston; 305. a sensor; 4. an adjustment mechanism; 401. a valve body; 402. a butterfly valve plate; 403. a shaft sleeve; 404. a meshing gear set; 405. a first motor; 406. a cannula holder; 407. a hand-operated wheel; 408. a signal block; 5. a pressurizing assembly; 501. a pressurized pump body; 502. a bearing housing; 503. a second motor; 504. rotating the rod; 505. a turbine blade.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

As shown in fig. 1, 2, 3, 4, and 5, the present embodiment provides a central water supply monitoring and management device, which includes a support assembly 1 and an adjusting mechanism 4, wherein a pipeline assembly 2 is disposed on the support assembly 1, a pressure measuring assembly 3 is disposed at an edge side of the pipeline assembly 2, and the pipeline assembly 2 is provided with the adjusting mechanism 4 in a sleeved manner;

the adjusting mechanism 4 comprises a valve body 401, a butterfly valve plate 402, a shaft sleeve 403, an engaging gear set 404, a first motor 405, a sleeve seat 406, a hand wheel 407 and a signal block 408, the valve body 401 is sleeved on the pipeline assembly 2, the butterfly valve plate 402 is arranged inside the valve body 401, the shaft sleeve 403 connected with a bearing is arranged above the butterfly valve plate 402, the engaging gear set 404 connected with a bearing is arranged above the shaft sleeve 403, the engaging gear set 404 connected with a bearing is connected with an output end of the first motor 405, the sleeve seat 406 is arranged above the valve body 401, the hand wheel 407 is arranged on one side of the sleeve seat 406, the signal block 408 is arranged on the top side of the first motor 405, and a pipeline on one side of the valve body 401 is connected with the supercharging assembly 5.

The valve body 401, the first motor 405 and the central axis of the sleeve seat 406 are in the same straight line, the meshing gear set 404 is of two groups of mutually meshed vertical gears, and the butterfly valve plate 402 is of a butterfly structure.

In this embodiment, when the signal block 408 receives a pressure signal, the first motor 405 outputs power to drive the output end to rotate, so that the shaft sleeve 403 can drive the butterfly valve plate 402 to operate, the valve body 401 is opened and adjusted to facilitate the water body to flow out through the valve body 401, and when the first motor 405 cannot adjust the flow rate, the hand wheel 407 on one side of the adjusting sleeve seat 406, which can be manually operated by a user, drives the meshing gear set 404 to adjust the butterfly valve plate 402 below the shaft sleeve 403 to achieve the adjusting effect.

The support assembly 1 comprises a base plate 101 and support sleeves 102, wherein a plurality of groups of support sleeves 102 distributed in parallel are arranged above the base plate 101.

In this embodiment, the bottom plate 101 and the support sleeve 102 can be matched to each other to support the pipe assembly 2.

The pipeline assembly 2 comprises a water inlet 201, a flange 202, a main pipe 203 and a water outlet 204, wherein the main pipe 203 is sleeved on the inner side of the support pipe sleeve 102, one end of the main pipe 203 is connected with the water inlet 201 through a bolt of the flange 202, and the other end of the main pipe 203 is provided with the water outlet 204.

In this embodiment, the two ends of the main pipe 203 are bolted to the upper water inlet 201 and the water outlet 204 by the flange 202, and the water enters the main pipe 203 through the water inlet 201, and after pressurization, the water is output through the water outlet 204, so that water supply is facilitated.

The pressure measuring assembly 3 comprises a side pipe sleeve 301, a spring seat 302, a push rod 303, a piston 304 and a sensor 305, wherein the side pipe sleeve 301 is arranged on one side of the main pipe 203, the spring seat 302 is arranged at one end of the side pipe sleeve 301, the spring seat 302 penetrates through the side pipe sleeve 301 to be connected with the push rod 303, the piston 304 is arranged at one end of the push rod 303, the sensor 305 is arranged at one end of the spring seat 302, and the sensor 305 is used for connecting the measured water body pressure to a signal block 408 through a signal line.

In this embodiment, when the water body enters the inner side of the main tube 203, the water body transmits the acting force of the water pressure to the push rod 303 by contacting the piston 304, so that the push rod 303 transmits the water pressure to the spring seat 302, and transmits the measured pressure to the signal block 408 through the signal line by using the sensor 305 on one side of the spring seat 302.

The pressurizing assembly 5 comprises a pressurizing pump body 501, a bearing sleeve 502, a second motor 503, a rotating rod 504 and a turbine blade 505, the pressurizing pump body 501 is connected with the valve body 401 through a pipeline, the bearing sleeve 502 is arranged on the inner side of the pressurizing pump body 501, the bearing sleeve 502 is connected with the output end of the second motor 503, the output end of the second motor 503 penetrates through the bearing sleeve 502 to be connected with the rotating rod 504, the turbine blade 505 is arranged on the outer side of the rotating rod 504, and the second motor 503 is connected with the signal block 408 through a conducting wire.

In this embodiment, the water body flows into the pressurizing pump body 501, the pressurizing operation can be performed according to the needs of the user, and the second motor 503 is started to output power to drive the rotating rod 504, so as to drive the turbine blade 505 below the bearing sleeve 502 to rotate at a high speed to rapidly drive the water body for driving, thereby achieving the pressurizing effect.

The working principle of the central water supply monitoring and managing device is as follows: as shown in fig. 1-5, firstly, the water enters the main body pipe 203 through the water inlet 201, when the water enters the inner side of the main body pipe 203, the water transmits the acting force of the water pressure to the push rod 303 through the contact piston 304, so that the push rod 303 transmits the water pressure to the spring seat 302, and the sensor 305 on one side of the spring seat 302 transmits the measured pressure to the signal block 408 through the signal line, when the signal block 408 receives the pressure signal, the first motor 405 outputs power to drive the output end to rotate, so that the shaft sleeve 403 can drive the butterfly valve plate 402 to operate, so as to open and adjust the valve body 401, so that the water flows out through the valve body 401, and then the water flows into the inner side of the pressurization pump body 501, the pressurization operation can be performed according to the needs of the user, the second motor 503 is started to output power to drive the rotating rod 504, so as to drive the turbine blade 505 below the bearing sleeve 502 to rotate at a high speed to drive the water to drive rapidly, the effect of pressurization is achieved, and the effect of water supply is conveniently achieved through the output device of the water outlet 204 after pressurization is completed.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. A central water supply monitoring management device comprises a supporting component (1) and an adjusting mechanism (4), and is characterized in that: a pipeline assembly (2) is arranged on the supporting assembly (1), a pressure measuring assembly (3) is arranged on the side of the pipeline assembly (2), and a sleeved adjusting mechanism (4) is arranged on the pipeline assembly (2);

the adjusting mechanism (4) comprises a valve body (401), a butterfly valve plate (402), a shaft sleeve (403), a meshing gear set (404), a first motor (405), a sleeve seat (406), a hand wheel (407) and a signal block (408), the valve body (401) is sleeved on the pipeline assembly (2), a butterfly valve plate (402) is arranged inside the valve body (401), a shaft sleeve (403) connected with a bearing is arranged above the butterfly valve plate (402), a meshing gear set (404) connected with a bearing is arranged above the shaft sleeve (403), and the meshing gear set (404) is connected with the output end of a first motor (405), a sleeve seat (406) is arranged above the valve body (401), a hand-operated wheel (407) is arranged on one side of the sleeve seat (406), the top side of the first motor (405) is provided with a signal block (408), and a pipeline on one side of the valve body (401) is connected with a pressurizing assembly (5).

2. The central water supply monitoring and managing device as claimed in claim 1, wherein: the valve body (401) and the first motor (405) are in the same straight line with the central axis of the sleeve seat (406), the meshing gear set (404) is of two groups of mutually meshed vertical gears, and the butterfly valve plate (402) is of a butterfly structure.

3. The central water supply monitoring and managing device as claimed in claim 2, wherein: the supporting assembly (1) comprises a bottom plate (101) and supporting pipe sleeves (102), wherein a plurality of groups of supporting pipe sleeves (102) distributed in parallel are arranged above the bottom plate (101).

4. A central water supply monitoring and management device according to claim 3, characterized in that: the pipeline assembly (2) comprises a water inlet (201), a flange plate (202), a main pipe (203) and a water outlet (204), the main pipe (203) is sleeved on the inner side of the support pipe sleeve (102), one end of the main pipe (203) is connected with the water inlet (201) through the flange plate (202) in a bolt mode, and the water outlet (204) is formed in the other end of the main pipe (203).

5. The central water supply monitoring and managing device as claimed in claim 4, wherein: the pressure measuring component (3) comprises a side pipe sleeve (301), a spring seat (302), a push rod (303), a piston (304) and a sensor (305), the side pipe sleeve (301) is arranged on one side of the main pipe (203), the spring seat (302) is arranged at one end of the side pipe sleeve (301), the side pipe sleeve (301) is connected with the push rod (303) in a penetrating mode, the piston (304) is arranged at one end of the push rod (303), the sensor (305) is arranged at one end of the spring seat (302), and the sensor (305) is connected with the signal block (408) through a signal line.

6. The central water supply monitoring and managing device as claimed in claim 2, wherein: pressure boost subassembly (5) are including the pressurization pump body (501), bearing housing (502), second motor (503), rotary rod (504) and turbine blade (505), there is valve body (401) through pipe connection in the pressurization pump body (501), the inboard of the pressurization pump body (501) is provided with bearing housing (502), bearing housing (502) are connected with the output of second motor (503), the output of second motor (503) runs through bearing housing (502) is connected with rotary rod (504), just the outside of rotary rod (504) is provided with turbine blade (505), second motor (503) pass through the wire with signal piece (408) are connected.

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