CN216843607U - Remote monitoring type natural gas amount control device for float glass production line - Google Patents

Abstract

The utility model discloses a remote monitoring formula float glass production line natural gas volume controlling means, its technical scheme is: including house steward, cross joint and three branch pipe one, house steward all with cross joint fixed connection with three branch pipe one, three branch pipe one side all is equipped with complementary unit, complementary unit includes the shell, the inside fixedly connected with valve body of shell, the inside admission line that is equipped with of valve body, inside admission line one end extends to the shell, the beneficial effects of the utility model are that: the natural gas flow rate control device has the advantages that the natural gas flow rate can be accurately controlled by supplementing the natural gas flow rate control device and the natural gas flow rate control device, so that the problems that the conventional natural gas flow rate control device is inconvenient to control the natural gas flow rate when in use, poor in practicability, incapable of well controlling the natural gas flow rate in the branch pipe and unsatisfactory in control effect can be solved.

Description

Remote monitoring type natural gas amount control device for float glass production line

Technical Field

The utility model relates to a float glass production facility technical field, concretely relates to remote monitoring formula float glass production line natural gas volume controlling means.

Background

The melting furnace is one of three thermal equipment in float glass production equipment, a large amount of natural gas is needed in the melting process of the melting furnace as a combustion medium, and the float glass has wide application and is divided into colored glass, a float silver mirror, float glass/automobile windshield level, float glass/various deep processing levels, float glass/scanner level, float glass/coating level and float glass/mirror making level;

need use the natural gas as burning medium when producing float glass, and need carry the natural gas through a plurality of branch pipes when producing, and need regulate and control the inside gas transmission pressure of interior branch pipe when carrying, also be exactly the velocity of flow of control natural gas, just so need use natural gas volume controlling means, and current natural gas volume controlling means is comparatively inconvenient when using the velocity of flow of control to the natural gas, and the practicality is relatively poor, the natural gas flow in the control branch pipe that can not be fine, control effect is unsatisfactory, consequently need improve.

SUMMERY OF THE UTILITY MODEL

Therefore, the utility model provides a remote monitoring formula float glass production line natural gas volume controlling means through the design of complementary unit to solve the problem among the background art.

In order to achieve the above object, the present invention provides the following technical solutions: the remote monitoring type natural gas amount control device for the float glass production line comprises a main pipe, a four-way joint and three branch pipes I, wherein the main pipe and the three branch pipes I are fixedly connected with the four-way joint, and auxiliary mechanisms are arranged on one sides of the three branch pipes;

the auxiliary mechanism includes the shell, the inside fixedly connected with valve body of shell, the inside admission line that is equipped with of valve body, admission line one end extends to inside the shell, branch pipe one end runs through inside the shell and extends to the admission line, the inside control assembly that is equipped with of admission line, the inside pipeline of giving vent to anger that is equipped with of valve body, the pipeline of giving vent to anger is located the admission line bottom, it is outside that pipeline one end of giving vent to anger extends to shell one side, shell top fixedly connected with motor, motor output shaft fixedly connected with pivot one, the inner wall is connected in valve body bottom to a pivot bottom, a fixed cover in the outside of pivot is equipped with helical blade, helical blade is located inside the valve body, the outside branch pipe two that is equipped with in shell one side, two one end of branch pipe extend to give vent to anger inside the pipeline and with the pipeline fixed connection of giving vent to anger.

Preferably, the fixed sleeve outside the valve body is provided with a fixed block, and the fixed block is fixedly connected with the shell.

Preferably, the air inlet pipeline is fixedly connected with the valve body, and the first branch pipe is fixedly connected with the shell and the air inlet pipeline.

Preferably, the air outlet pipeline is fixedly connected with the shell and the valve body.

Preferably, the control assembly comprises a sealing ring, the sealing ring is fixedly connected inside the air inlet pipeline, a pneumatic actuator is fixedly connected to the top of the shell and located on one side of the motor, a second rotating shaft is fixedly connected to the bottom end of the pneumatic actuator, and the bottom end of the second rotating shaft penetrates through the shell and the sealing ring and is connected to the inner wall of the bottom of the air inlet pipeline.

Preferably, the fixed cover in the outside of pivot is equipped with the plectane, the plectane is located inside the sealing washer and laminates mutually with the sealing washer inner wall, the sealing washer is made by rubber materials, pivot two and sealing washer sliding connection.

Preferably, the inner wall of the other side of the shell is fixedly connected with an electric cylinder, the electric cylinder is positioned at the top of the air inlet pipeline, one end of the electric cylinder is fixedly connected with a movable plate, the movable plate is in contact with the inner wall of the top of the shell and the top of the air inlet pipeline and is in sliding connection with the inner wall of the top of the shell and the top of the air inlet pipeline, a clamping block is fixedly connected to one side of the movable plate, and the clamping block is in contact with the rotating shaft.

Preferably, the branch pipe is externally provided with a one-way valve and a pressure sensor.

Preferably, the first rotating shaft is connected with the housing and the valve body through a sealing bearing.

Preferably, the second rotating shaft is connected with the second air inlet pipeline and the shell through a sealing bearing.

The utility model has the advantages that:

the utility model can rotate the second rotating shaft by the operation of the pneumatic actuator, the second rotating shaft drives the circular plate to rotate, so that the circular plate can rotate in the sealing ring, the air inlet channel can be opened, the natural gas can circulate, the flow rate of the natural gas can be controlled by controlling the rotating angle of the circular plate, the first rotating shaft can rotate by controlling the operation of the motor, thereby the helical blade rotates, the flow rate of the natural gas can be controlled by controlling the rotating direction and the rotating speed of the helical blade, the flow rate of the natural gas can be accurately controlled by supplementing the two, thereby the flow rate of the natural gas can be well controlled, the supply quantity of the natural gas can be accurately controlled, and the problem that the conventional natural gas quantity control device is inconvenient to control the flow rate of the natural gas when in use and has poor practicability is solved, the natural gas flow speed in the branch pipe cannot be well controlled, and the control effect is not ideal.

Drawings

In order to more clearly illustrate the embodiments of the present invention 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. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used to cooperate with the contents disclosed in the specification for the people familiar with the art to understand and read, and are not used to limit the practical limit condition of the present invention, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the coverage range of the technical contents disclosed in the present invention without affecting the function and the achievable purpose of the present invention

Fig. 1 is a schematic view of the overall structure provided by the present invention;

fig. 2 is an enlarged view of a point a in fig. 1 according to the present invention;

fig. 3 is an enlarged view of the point B in fig. 1 provided by the present invention;

fig. 4 is a perspective view of the fixture block and the moving plate provided by the present invention;

in the figure: the device comprises a main pipe 1, a four-way joint 2, a branch pipe I3, a shell 4, a valve body 5, an air inlet pipeline 6, an air outlet pipeline 7, a motor 8, a rotating shaft I9, a helical blade 10, a branch pipe II 11, a fixed block 12, a sealing ring 13, a pneumatic actuator 14, a rotating shaft II 15, a circular plate 16, an electric cylinder 17, a movable plate 18, a fixed block 19, a one-way valve 20 and a pressure sensor 21.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Referring to the attached drawings 1-4, the utility model provides a remote monitoring type float glass production line natural gas quantization control device, which comprises a main pipe 1, a four-way joint 2 and three branch pipes I3, wherein the main pipe 1 and the three branch pipes I3 are fixedly connected with the four-way joint 2, and the three branch pipes I3 are provided with auxiliary mechanisms on the sides;

the auxiliary mechanism comprises a shell 4, a valve body 5 is fixedly connected inside the shell 4, an air inlet pipeline 6 is arranged inside the valve body 5, one end of the air inlet pipeline 6 extends into the shell 4, one end of a branch pipe 3 penetrates through the shell 4 and extends into the air inlet pipeline 6, a control assembly is arranged inside the air inlet pipeline 6, an air outlet pipeline 7 is arranged inside the valve body 5, the air outlet pipeline 7 is located at the bottom of the air inlet pipeline 6, one end of the air outlet pipeline 7 extends to the outside of one side of the shell 4, a motor 8 is fixedly connected to the top of the shell 4, an output shaft of the motor 8 is fixedly connected with a first rotating shaft 9, the bottom end of the first rotating shaft 9 is connected to the inner wall of the bottom of the valve body 5, a spiral blade 10 is fixedly sleeved outside the first rotating shaft 9, the spiral blade 10 is located inside the valve body 5, a branch pipe two 11 is arranged outside one side of the shell 4, and one end of the branch pipe two 11 extends into the air outlet pipeline 7 and is fixedly connected with the air outlet pipeline 7;

and the air inlet pipeline 6 is fixedly connected with the valve body 5, and the branch pipe I3 is fixedly connected with the shell 4 and the air inlet pipeline 6.

The air outlet pipeline 7 is fixedly connected with the shell 4 and the valve body 5.

The control assembly comprises a sealing ring 13, the sealing ring 13 is fixedly connected inside the air inlet pipeline 6, a pneumatic actuator 14 is fixedly connected to the top of the shell 4, the pneumatic actuator 14 is located on one side of the motor 8, a rotating shaft II 15 is fixedly connected to the bottom end of the pneumatic actuator 14, and the bottom end of the rotating shaft II 15 penetrates through the shell 4 and the sealing ring 13 and is connected to the inner wall of the bottom of the air inlet pipeline 6.

A circular plate 16 is fixedly sleeved outside the second rotating shaft 15, the circular plate 16 is positioned inside the sealing ring 13 and is attached to the inner wall of the sealing ring 13, the sealing ring 13 is made of rubber materials, and the second rotating shaft 15 is connected with the sealing ring 13 in a sliding mode.

In this embodiment, the pneumatic actuator 14 can rotate the second rotating shaft 15 when operating, the second rotating shaft 15 rotates to drive the circular plate 16 to rotate, so that the circular plate 16 can rotate inside the sealing ring 13, so that the air inlet channel can be opened, so that natural gas can circulate, the flow rate of the natural gas can be controlled by controlling the rotation angle of the circular plate 16, and the first rotating shaft 9 can rotate by controlling the operation of the motor 8, so that the helical blade 10 rotates, the flow rate of the natural gas can be controlled by controlling the rotation direction and the rotation speed of the helical blade 10, and the flow rate of the natural gas can be accurately controlled by complementing the two, so that the flow rate of the natural gas can be well controlled, and the supply amount of the natural gas can be accurately controlled;

wherein, in order to realize reinforced purpose, this device adopts following technical scheme to realize: a fixed block 12 is fixedly sleeved outside the valve body 5, the fixed block 12 is fixedly connected with the shell 4, and the fixed block 12 can reinforce the valve body 5;

wherein, in order to realize the purpose of protection, this device adopts the following technical scheme to realize: the inner wall of the other side of the shell 4 is fixedly connected with an electric cylinder 17, the electric cylinder 17 is positioned at the top of the air inlet pipeline 6, one end of the electric cylinder 17 is fixedly connected with a moving plate 18, the moving plate 18 is in contact with the inner wall of the top of the shell 4 and the top of the air inlet pipeline 6 and is in sliding connection with the inner wall, one side of the moving plate 18 is fixedly connected with a clamping block 19, the clamping block 19 is in contact with the second rotating shaft 15, the second rotating shaft 15 can be limited by the design of the electric cylinder 17, the clamping block 19 and the moving plate 18, and therefore the phenomenon that the second rotating shaft 15 rotates when the pneumatic actuator 14 works in error control can be avoided, and the flow rate of natural gas can be prevented from being changed;

wherein, in order to realize avoiding appearing the purpose of backward flow phenomenon, this device adopts following technical scheme to realize: the check valve 20 and the pressure sensor 21 are arranged outside the second branch pipe 11, the pressure sensor 21 can detect the flow rate of the natural gas inside the second branch pipe 11, and the check valve 20 can avoid the phenomenon that the flow rate of the natural gas is suddenly reduced and backflow occurs;

wherein, in order to realize the purpose of avoiding appearing the phenomenon of gas leakage, this device adopts following technical scheme to realize: 9. the first rotating shaft 9 is connected with the shell 4 and the valve body 5 through a sealing bearing, the second rotating shaft 15 is connected with the second air inlet pipeline 6 and the shell 4 through a sealing bearing, and the phenomenon of air leakage can be avoided through connection of the sealing bearing.

The utility model discloses a use as follows: when the utility model is used, natural gas enters the four-way joint 2 through the header pipe 1 and then enters the air inlet pipeline 6 through the branch pipe I3, and when the flow rate of the natural gas needs to be controlled, the remote control motor 8, the pneumatic actuator 14 and the electric cylinder 17 work through the Internet of things;

firstly, the electric cylinder 17 is controlled to work through the Internet of things, so that the moving plate 18 can move rightwards, the clamping block 19 can be enabled not to be in contact with the second rotating shaft 15, then the pneumatic actuator 14 is controlled to work, the pneumatic actuator 14 works to drive the second rotating shaft 15 to rotate, the second rotating shaft 15 rotates to drive the circular plate 16 to rotate, and therefore the circular plate 16 can rotate inside the sealing ring 13, an air inlet channel can be opened, natural gas can circulate, the natural gas enters the valve body 5 through the first branch pipe 3 and the air inlet pipeline 6 and finally flows out through the air outlet pipeline 7 and the second branch pipe 11, the pressure sensor 21 can detect the pressure value of the natural gas inside the second branch pipe 11 when the natural gas flows out, the pressure value of the natural gas is known, the larger the pressure value indicates that the flow rate of the natural gas is faster, and the flow rate of the natural gas can be controlled by controlling the rotating angle of the circular plate 16, if the opening and closing of the circular plate 16 do not obtain the required flow velocity, the motor 8 is controlled to work to enable the first rotating shaft 9 to rotate, so that the spiral blade 10 rotates, the flow velocity of natural gas can be controlled through the rotating direction and the rotating speed of the spiral blade 10, the flow velocity of the natural gas can be accurately controlled through the mutual assistance of the rotating direction and the rotating speed, the flow velocity of the natural gas is well controlled, the supply quantity of the natural gas is accurately controlled, the problems that an existing natural gas flow control device is inconvenient to control the flow velocity of the natural gas when in use, the practicability is poor, the natural gas flow velocity in the branch pipe cannot be well controlled, and the control effect is not ideal are solved.

The above is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it into an equivalent technical solution by using the technical solutions described above. Therefore, any simple modifications or equivalent replacements made according to the technical solution of the present invention belong to the scope of the claimed invention as far as possible.

Claims (10)

1. Remote monitoring formula float glass production line natural gas volume controlling means, including house steward (1), four-way connection (2) and three branch pipe one (3), its characterized in that: the main pipe (1) and the three first branch pipes (3) are fixedly connected with the four-way joint (2), and auxiliary mechanisms are arranged on the sides of the three first branch pipes (3);

the auxiliary mechanism comprises a shell (4), a valve body (5) is fixedly connected inside the shell (4), an air inlet pipeline (6) is arranged inside the valve body (5), one end of the air inlet pipeline (6) extends to the inside of the shell (4), one end of a branch pipe (3) penetrates through the shell (4) and extends to the inside of the air inlet pipeline (6), a control assembly is arranged inside the air inlet pipeline (6), an air outlet pipeline (7) is arranged inside the valve body (5), the air outlet pipeline (7) is located at the bottom of the air inlet pipeline (6), one end of the air outlet pipeline (7) extends to the outside of one side of the shell (4), a motor (8) is fixedly connected to the top of the shell (4), a first rotating shaft (9) is fixedly connected to an output shaft of the motor (8), the bottom end of the first rotating shaft (9) is connected to the inner wall of the bottom of the valve body (5), a first rotating shaft (9) is externally fixed in a sleeve manner and provided with a spiral blade (10), helical blade (10) are located inside valve body (5), shell (4) one side outside is equipped with branch pipe two (11), branch pipe two (11) one end extend to give vent to anger inside pipeline (7) and with give vent to anger pipeline (7) fixed connection.

2. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: the fixed cover in valve body (5) outside is equipped with fixed block (12), fixed block (12) and shell (4) fixed connection.

3. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: and the air inlet pipeline (6) is fixedly connected with the valve body (5), and the branch pipe I (3) is fixedly connected with the shell (4) and the air inlet pipeline (6).

4. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: and the air outlet pipeline (7) is fixedly connected with the shell (4) and the valve body (5).

5. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: the control assembly comprises a sealing ring (13), the sealing ring (13) is fixedly connected inside the air inlet pipeline (6), a pneumatic actuator (14) is fixedly connected to the top of the shell (4), the pneumatic actuator (14) is located on one side of the motor (8), a second rotating shaft (15) is fixedly connected to the bottom end of the pneumatic actuator (14), and the bottom end of the second rotating shaft (15) penetrates through the shell (4) and the sealing ring (13) and is connected to the inner wall of the bottom of the air inlet pipeline (6).

6. The remote monitoring type natural gas amount control device for the float glass production line according to claim 5, wherein: the fixed cover in pivot two (15) outside is equipped with plectane (16), plectane (16) are located sealing washer (13) inside and laminate mutually with sealing washer (13) inner wall, sealing washer (13) are made by rubber materials, pivot two (15) and sealing washer (13) sliding connection.

7. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: the utility model discloses a portable air conditioner, including shell (4), electronic jar (17) of shell (4) opposite side inner wall fixedly connected with, electronic jar (17) are located admission line (6) top, electronic jar (17) one end fixedly connected with movable plate (18), movable plate (18) contact and rather than sliding connection with shell (4) top inner wall and admission line (6) top, movable plate (18) one side fixedly connected with fixture block (19), fixture block (19) contact with pivot two (15).

8. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: and a one-way valve (20) and a pressure sensor (21) are arranged outside the second branch pipe (11).

9. The remote monitoring type natural gas amount control device for the float glass production line according to claim 1, wherein: and the first rotating shaft (9) is connected with the shell (4) and the valve body (5) through a sealing bearing.

10. The remote monitoring type natural gas amount control device for the float glass production line according to claim 5, wherein: and the second rotating shaft (15) is connected with the second air inlet pipeline (6) and the shell (4) through a sealing bearing.

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