BR112021013984B1 - FLOW MONITORING DEVICE FOR LIQUEFIED GAS TANK - Google Patents

Abstract

Flow monitoring device for liquefied gas tank. The present invention relates to a flow monitoring device for a liquefied gas tank, comprising a pressure valve, a pulse valve, a flow meter, a dispensing outlet, a button rod, a switch handle, a commutator shaft, a gas inlet device, a support member, and a clamping member. When the above frame monitoring device is used, a knob is rotated, the knob rod is connected with the tap-changer crank to rotate the tap-changer shaft, and a pressure rod of the gas inlet device is pushed out of the commutator shaft, thereby triggering a gas outlet device from a gas cylinder. when the button is in an off state, the button is pressed, the button rod is on and the switch handle presses a switch spring on the switch handle, the switch handle directs a clamping column on the clamping member to push a switch handle. clamping ring away, and the bottled gas cylinder is disengaged from a gas cylinder ring groove of the gas inlet device, when the knob is in an on state, the clamping ring cannot be pulled away, and the Bottled gas cylinder cannot be disengaged from the gas cylinder ring groove, thus preventing energy waste and safety problem caused by gas leakage.

Description

FIELD OF TECHNIQUE

[001] The present invention relates to the field of flow meters and, in particular, to a flow monitoring device for a liquefied gas tank.

FUNDAMENTALS OF THE INVENTION

[002] Natural gas transport infrastructure in pipelines is not popular in some places, requiring the purchase of bottled liquefied gas. However, manual valves arranged on the gas outlets of existing liquefied gas tanks need to be manually closed after use, which often causes natural gas to leak. In most existing gas pressure valves, a switching hook is used to hook a gas outlet end of a gas cylinder, while a valve needle is moved down to actuate a gas outlet device from the gas cylinder. gas, thereby introducing the gas into a valve body, which can cause gas leakage during operation. If the liquefied gas cylinder is disengaged from the pressure valve during use, more gas will leak out, resulting in further damage.

SUMMARY OF THE INVENTION

[003] One embodiment of the present invention provides a flow monitoring device for a liquefied gas tank to solve the problem of gas leakage caused by disengagement of a liquefied gas cylinder from a pressure valve during use. In order to have a basic understanding of some aspects of the disclosed modalities, a brief summary is provided below. This summary is not a general review, nor is it intended to determine the key elements/important constituents or to describe the scope of protection of these modalities. Its sole purpose is to present some concepts in simple forms as a prelude to the more detailed description below.

[004] In accordance with a first aspect of embodiments of the present invention, there is provided a flow monitoring device for a liquefied gas tank, including a compartment and a pressure valve, a switch handle, a switch shaft and a gas inlet device arranged in the compartment, wherein the gas inlet device is arranged at the bottom of the pressure valve, a gas outlet end of the pressure valve is connected to a gas inlet end of a pressure valve. pulse, one gas outlet end of the pulse valve is connected to a dispensing outlet via a flow meter, a button rod vertically penetrates a side wall of the compartment, a button is arranged at an exposed end of the button, the end of the button rod in the housing is fixedly connected to a plug-in rod of the switch handle by means of a screw, a gas inlet nozzle and is arranged in the gas inlet device, a push rod and a push rod spring are arranged in the gas inlet nozzle, the push rod spring is coated outside the push rod, one end of the push rod far away of the pressure rod spring penetrates vertically into a gas cavity of the pressure valve, the pressure rod is in contact with one side of a first protrusion of the switch shaft, the switch shaft is rotatably arranged in the gas cavity of the body of the valve, a first stop block and a second stop block are arranged on an outer wall of the switch shaft, a second boss is provided at one end of the switch shaft close to the switch handle, a third stop block is arranged at the top of the second boss and in a switch hole of the switch handle, a switch pin is arranged vertically in a wall of the switch hole, the second boss abuts against one end of a switch spring, the other end of the switch spring abuts the bottom of the switch hole, and a gas cylinder ring groove and a fourth stop block are arranged at the bottom of the inlet device. gas near the compartment.

[005] A support member and a fixing member are arranged in the compartment, and the support member is fixedly connected to the bottom of the compartment; a first support bar, a second support bar, a first anchor post and a first step are arranged on top of the support member; the switch handle is provided with a first ring groove, the clamping member is provided with a clamping ring and a second clamping column, the second clamping column is driven by the clamping ring and the first ring groove pushing the ring of clamping away from the gas inlet nozzle, a direction of movement of the clamping ring is perpendicular to a geometric axis of the gas inlet nozzle, a clamping slot is provided at the bottom of the clamping member, one side of the second boss is in contact with an upper column of the clamping member, and the fourth stop block is clamped on top of the first step and clamping ring.

[006] A second slot is provided on one side of the third stop block away from the commutator spring, and the commutator pin extends into the second slot.

[007] A first ring groove is provided on the outer wall of the commutator shaft and an O-ring is arranged between the first ring groove and the wall of the pressure valve gas cavity.

[008] The commutator shaft, commutator spring, commutator crank and button rod are coaxial. The switch handle and plug-in rod are integrally formed; the commutator shaft, the first boss and the third stop block are integrally formed; the gas cylinder ring groove, the fourth stop block and the gas inlet nozzle are integrally formed; the first support bar, the second support bar, the first anchor post and the first step are integrally formed; and the clamping ring, clamping slot, second clamping post and upper post are integrally formed.

[009] In an exemplary arrangement, a flow monitoring device is provided for mounting on a gas cylinder. The flow monitoring device comprises a compartment and a pressure valve, a switch handle, a switch shaft, a gas inlet device and an attachment member arranged in the compartment, wherein the gas inlet device is arranged. at the bottom of the pressure valve, and the button stem extends through a side wall of the housing, a button is arranged on an exposed end of the button rod, the end of the button rod in the housing is coupled to the switch handle to rotate the commutator shaft when the knob is moved between a first state and a second state (e.g. between an 'ON' state and an 'OFF' state), a gas cylinder ring groove, to engage with ( or attach) the gas cylinder, is arranged at the bottom of the gas inlet device, the fixing member is provided with a fixing ring to fix the gas cylinder inside the gas cylinder ring groove. gas (e.g., when using the flow monitoring device with a gas cylinder, the clamping member clamp ring secures the gas cylinder inside the gas cylinder ring groove) and an upper column attached to the gas cylinder. clamping ring, where when the knob is in the first state (e.g. the 'ON' state), the upper column of the clamping member is clamped between the toggle shaft and the toggle handle so that the clamping ring is prevented from (or cannot be) moved away from the gas cylinder ring groove.

[010] The flow monitoring device may further comprise a pressure rod disposed in the gas inlet device and being in contact with the commutator shaft, with one end of the pressure rod extending into a gas cavity of the flow valve. pressure. In an exemplary arrangement, when the knob is rotated to the first state (e.g., the 'ON' state), the switch shaft is configured to push the pressure rod out of the pressure valve's gas cavity to actuate a gas cylinder gas outlet device.

[011] In an exemplary arrangement, when the button is in the second state (e.g., the 'OFF' state) and the button is pressed, the switch handle is configured to drive the clamping member to push the clamping ring to away from the gas cylinder ring groove in a direction perpendicular to an axis of the gas inlet device.

[012] The commutator shaft can be configured so that when the button is in the first state (e.g. 'ON' state), the commutator shaft is in a first rotated position in which the clamping member is clamped between the switch shaft and the switch handle and when the knob is in the second state (e.g. 'OFF' state), the switch shaft is in a second rotated position, which is different from the first rotated position in which the member clamp is not clamped between the commutator shaft and the commutator crank. For example, the flow monitoring device may include a first stop block disposed on an outer wall of the switch shaft. In this exemplary arrangement, the first stop block is arranged on the outer wall of the switch shaft so that when the button is in the first state (e.g. 'ON' state) and the switch shaft is in the first rotated position, the clamping member is clamped between the first stop block disposed on an outer wall of the switch shaft and the switch handle and when the switch is in the second state (e.g. 'OFF' state) and the switch shaft is in the second different rotated position, the clamping member is not clamped between the first stop block and the switch handle.

[013] Knob can be rotated between first state and second state.

[014] The commutator shaft can be rotatably arranged in a pressure valve gas cavity. A gas outlet end of the pressure valve may be coupled to a dispensing outlet. The gas outlet end of the pressure valve can be coupled to a distribution outlet via a flow meter.

[015] In an exemplary arrangement, when the flow monitoring device is mounted on the gas cylinder and the gas cylinder is secured by the fixing member inside the gas cylinder ring groove, when the knob is in the first state ( e.g. 'ON' state), and the upper column of the clamping member is clamped between the commutator shaft and the commutator crank so that the clamping ring is prevented from being pushed away from the cylinder ring groove gas cylinder, the gas cylinder cannot be disengaged from the gas cylinder ring groove.

[016] In an exemplary arrangement, when the flow monitoring device is mounted on a gas cylinder and the gas cylinder is secured by the fixing member inside the gas cylinder ring groove, when the knob is in the second state (e.g. 'OFF' state) and the button is pressed, the switch handle is set to drive the clamp member to push the clamp ring away from the gas cylinder ring groove in a direction perpendicular to a geometric axis of the gas inlet device so that the gas cylinder can be disengaged from the gas cylinder ring groove.

[017] The technical solution provided by the embodiments of the present invention may include the following beneficial effects: the anti-disassembly pressure valve with the above structure is used to access the gas, the knob is rotated, the knob rod is connected to the crank of commutator to rotate the commutator shaft and the rod of the gas inlet device is pushed out by the commutator shaft, thereby driving a gas outlet device of a gas cylinder. When the switch is in the OFF state, the switch is pressed, the linked button rod and the switch handle compress the switch spring on the switch handle, the switch handle drives the clamping column on the clamping member to push the ring away from clamping, the bottled gas cylinder is disengaged from the gas cylinder ring groove of the gas inlet device; When the button is in an ON state, even if the button is pressed, the upper column on the clamping member is caught between the commutator shaft and the commutator handle, and the clamping ring cannot be pushed, thus preventing the gas cylinder is disengaged from the gas cylinder ring groove during use, effectively avoiding energy wastage and safety problems caused by gas leakage.

[018] It should be understood that the above general description and the following detailed description are merely exemplary and illustrative and should not limit the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[019] Figure 1 is a schematic external view of the present invention;

[020] Figure 2 is a schematic view of an internal structure of the present invention;

[021] Figure 3 is a schematic cross-sectional view of a partial structure taken along line A-A in Figure 2;

[022] Figure 4 is a schematic structural view of a switch handle, a switch shaft and a gas inlet device;

[023] Figure 5 is a schematic structural view of a support member and an anchor member.

DETAILED DESCRIPTION

[024] The present invention will be described in more detail below with reference to the accompanying drawings and specific embodiments. However, it should be noted that the description of the following embodiments is schematic and does not constitute a specific limitation on the present invention.

[025] With reference to Figure 1 to Figure 5, a flow monitoring device for a liquefied gas tank is provided, including a compartment 1 and a pressure valve 2, a switch handle 6, a switch shaft 7 and a gas inlet device 8 arranged in the compartment 1, wherein the gas inlet device 8 is arranged in the lower part of the pressure valve 2, a gas outlet end of the pressure valve 2 is connected to an end of gas inlet of a pulse valve 3, a gas outlet end of the pulse valve 3 is connected to a distribution outlet 11 through a flow meter 4, a button rod 5 vertically penetrates a side wall of the compartment 1 , a button 5a is arranged at the exposed end of the button rod 5, the end of the button rod 5 in the housing 1 is fixedly connected to a socket rod 6d of the switch handle 6 through a screw 11, a socket for in The gas supply 8c is arranged in the gas inlet device 8, a pressure rod 13 and a pressure rod spring 13a are arranged in the gas inlet nozzle 8c, the pressure rod spring 13a is coated on the outside of the pressure rod 13, the end of the pressure rod 13 away from the pressure rod spring 13a vertically penetrates a gas cavity of the pressure valve 2, the pressure rod 13 is in contact with one side of a first protrusion 7a of the switch shaft 7, the switch shaft 7 is rotatably arranged in the gas cavity of the valve body 2, a first stop block 7c and a second stop block 7d are arranged on the outer wall of the switch shaft 7, a second boss 7e is provided at the end of the switch shaft 7 close to the switch handle 6, a third stop block 7f is arranged on top of the second boss 7e and in a switch hole 6b of the switch handle 6, a switch 6c and is arranged vertically on a wall of the switch hole 6b, the second projection 7e abuts one end of a switch spring 12, the other end of the switch spring 12 abuts the underside of the switch hole 6b and a ring groove gas cylinder 8a and a fourth stop block 8b are arranged at the bottom of the gas inlet device 8 near compartment 1.

[026] Flow meter may also be referred to as a measurement sensor and may include any suitable type of flow meter or measurement sensor, such as a mechanical meter, an ultrasonic sensor, a piezoelectric sensor, a Microelectromechanical System sensor ( MEMS). The MEMS sensor may include or use a thermopile or thermistor.

[027] A support member 9 and a fixing member 10 are arranged in the compartment 1, and the support member 9 is fixedly connected to the bottom of the compartment 1. A first support bar 9a, a second support bar 9b , a first clamping column 9c and a first step 9d are arranged on top of the support member 9. The switch handle 6 is provided with a first ring groove 6a, the clamping member 10 is provided with a clamping ring 10a and a second clamping post 10c, the second clamping post 10c driven by clamping ring 10a and the first clamping ring groove 6a pushes clamping ring 10a away from gas inlet nozzle 8c, the direction of movement of the clamping ring 6a. fixture 10a is perpendicular to the geometric axis of the gas inlet nozzle 8c. A fixing slot 10b is provided at the bottom of the fixing member 10, one side of the second projection 7e is in contact with an upper column 10d of the fixing member 10 and the fourth stop block 8b is fixed on top of the first step 9d and the fixing ring 10a.

[028] A second slot 7f1 is provided on one side of the third stop block 7f away from the switch spring 12 and the switch pin 6c extends into the second slot 7f1.

[029] A second ring groove 7b is provided on the outer wall of the switch shaft 7 and an O-ring 14 is arranged between the second ring groove 7b and the wall of the gas cavity of the pressure valve 2.

[030] The commutator shaft 7, the commutator spring 12, the commutator crank 6 and the button rod 5 are coaxial.

[031] The switch handle 6 and the plug-in rod 6d are integrally formed; the switch shaft 7, the first boss 7a and the third stop block 7f are integrally formed; the gas cylinder ring groove 8a, the fourth stop block 8b and the gas inlet nozzle 8c are integrally formed; the first support bar 9a, the second support bar 9b, the first fixing post 9c and the first step 9d are integrally formed; and the clamping ring 10a, the clamping slot 10b, the second clamping post 10c and the upper post 10d are integrally formed.

[032] In this mode, flow meter 4 is a sonic flow meter, the 5a down button is in an OFF state and the 5a up button is in an ON state. Flow meter may also be referred to as a measurement sensor and can include any suitable type of flow meter or measurement sensor such as a mechanical meter, an ultrasonic sensor, a piezoelectric sensor, a Microelectromechanical Systems (MEMS) sensor. The MEMS sensor may include or use a thermopile or thermistor. The lower part of the clamping ring 10a is an inclined surface. When a gas inlet of the support member 9 is mounted on a gas cylinder, the gas cylinder pushes the clamping ring 10a away from the gas inlet nozzle 8c, the clamping ring 10a is connected to the upper column 10d to stop at the second stop block 7d, at the same time the second clamping column 10c drives the switch handle 6 to press the switch spring 12 and the gas cylinder slides into the gas cylinder ring groove 8a. After the gas cylinder slides into the gas cylinder ring groove 8a, the switch spring 12 is reset to restore the switch handle 6 and fastener 10 to their original positions (as shown in Figure 3) , and the locking ring 10a secures the gas cylinder within the gas cylinder ring groove 8a. During the gas cylinder assembly process, the first clamping column 9c moves back and forth within the clamping slot 10b with the expansion and contraction of the switch spring 12, which can limit the expansion and contraction range. of the switch spring 12 to protect the switch spring 12 most likely to deform. When the button 5a is in the OFF state, one side A of the first stop block 7c is in contact with the step of the pressure valve 2 and the first projection 7a is in contact with the pressure rod 13. During use, the button 5a is rotated from OFF to ON, the button rod 5 is connected to the switch handle 6, the switch shaft 7 is rotated, one side A of the second stop block 7d is in contact with the step of the pressure valve 2, and as the switch shaft 7 rotates, the first projection 7a pushes the pressure rod 13 out of the gas cavity of the pressure valve 2, thus driving a gas outlet device of the gas cylinder. When the button 5a is in the OFF state, the button 5a is pressed, the on button rod and the switch handle 6 compress the switch spring 12, the first ring groove 6a drives the second clamping post 10c to the left to pushing the clamping ring 10a away the gas inlet nozzle 8c and the bottled gas cylinder are disengaged from the gas cylinder ring groove 8a. When the button 5a is in the ON state, even if the button 5a is pressed, the upper column 10d is stuck between a B side of the first stop block 7c and the switch handle 6, the clamping ring 10a cannot be pushed to away from the gas inlet nozzle 8c and the bottled gas cylinder cannot be disengaged from the gas cylinder ring groove 8a. The gas cylinder is prevented from being disengaged from the gas cylinder ring groove during use, and energy wastage and safety problems caused by gas leakage are effectively avoided.

[033] The present invention can also cooperate with a GPRS or an SMS to communicate with a server, and the opening and closing of the valve of the present invention is controlled by a mobile phone (GPRS/SMS/Bluetooth, etc.) or magnetic cards (RFID) to realize the functions of real-time charging and deduction, intelligent data transmission, alarm, unlock prevention, and the like. The opening and closing of the valve of the present invention can be controlled by other wireless technologies such as Narrowband Internet of Things (NB-IOT), Bluetooth, GSM, WiFi, cellular technologies such as fifth generation (5G) cellular technologies. In regions without the natural gas pipeline network, people are relatively poor and cannot afford the cost of purchasing a full tank of liquefied gas, so most of them use charcoal and firewood as fuel for heating and cooking. Using Internet of Things technology and the unique mechanical design described above, liquefied gas can be used in poor regions every day with little money. After the refill expense is exhausted, the equipment automatically closes the valve until the next refill, and the valve can be reopened for use, so that everyone can use the liquefied gas.

[034] The flow monitoring device may also include an actuator. The actuator can be configured to control the opening and closing of the pressure valve to release or stop the flow of gas from the gas cylinder in response to wirelessly received commands.

[035] It will be clear from the above that the terms gas tank and gas cylinder are used interchangeably in the above description.

[036] The above description is merely of preferred embodiments of the present invention, and the present invention is not limited to the above specific embodiments. All technical solutions to achieve the objective of the present invention by means of the same means fall within the scope of protection of the present invention.

Claims (6)

1. Flow monitoring device for liquefied gas tank, CHARACTERIZED by the fact that it comprises a compartment (1) and a pressure valve (2), a switch handle (6), a switch shaft (7) and a gas inlet device (8) arranged in the compartment (1), wherein the gas inlet device (8) is arranged at the bottom of the pressure valve (2), a gas outlet end of the pressure valve ( 2) is connected to a gas inlet end of a pulse valve (3), a gas outlet end of the pulse valve (3) is connected to a delivery outlet via a flow meter (4), a button rod (5) penetrates vertically into a side wall of the compartment (1), a button (5a) is arranged at an exposed end of the button rod (5), one end of the button rod (5) in the compartment ( 1) is fixedly connected to a socket rod (6d) of the switch handle (6) via a screw (11), a nozzle gas inlet (8c) is arranged in the gas inlet device (8), a pressure rod (13) and a pressure rod spring (13a) are arranged in the gas inlet nozzle (8c), the spring rod (13a) is sheathed outside the pressure rod (13), one end of the pressure rod (13) away from the pressure rod spring (13a) penetrates vertically into a gas cavity of the pressure valve (2) ), the pressure rod (13) is in contact with one side of a first projection (7a) of the switch shaft (7), the switch shaft (7) is rotatably arranged in the gas cavity of the pressure valve (2) ), a first stop block (7c) and a second stop block (7d) are arranged on an outer wall of the switch shaft (7), a second boss (7e) is provided at one end of the switch shaft (7) ) close to the switch handle (6), a third stop block (7f) is arranged on top of the second boss (7e) and in a switch hole (6b) of the switch handle (6b). switch (6), a switch pin (6c) is arranged vertically in a wall of the switch hole (6b), the second projection (7e) abuts against one end of a switch spring (12), the other end of the spring of switch (12) abuts against the bottom of the switch hole (6b), and a gas cylinder ring groove (8a) and a fourth stop block (8b) are arranged at the bottom of the gas inlet device. (8) near the compartment (1). 2. Flow monitoring device for liquefied gas tank, according to claim 1, CHARACTERIZED by the fact that a support member (9) and a fixing member (10) are arranged in the compartment (1), and the support member (9) is fixedly connected to the lower part of the compartment (1); a first support bar (9a), a second support bar (9b), a first fixing post (9c) and a first step (9d) are arranged on top of the support member (9); the switch handle (6) is provided with a first ring groove (6a), the clamping member (10) is provided with a clamping ring (10a) and a second clamping column (10c), the second clamping column (10c) clamping (10c) driven by clamping ring (10a) and the first ring groove (6a) pushes clamping ring (10a) away from the gas inlet nozzle (8c), a direction of movement of clamping ring ( 10a) is perpendicular to a geometric axis of the gas inlet nozzle (8c), a clamping slot (10b) is provided at the bottom of the clamping member (10), one side of the second projection (7e) is in contact with an upper column (10d) of the clamping member (10), and the fourth stop block (8b) is fixed on top of the first step (9d) and the clamping ring (10a). 3. Flow monitoring device for liquefied gas tank, according to claim 1, CHARACTERIZED by the fact that a second slot (7f1) is provided on one side of the third stop block (7f) away from the switch spring ( 12), and the switch pin (6c) extends into the second slot (7f1). 4. Flow monitoring device for liquefied gas tank, according to claim 1, CHARACTERIZED by the fact that a second ring groove (7b) is provided on the external wall of the commutator shaft (7), and an O-ring (14) is arranged between the second ring groove (7b) and the gas cavity wall of the pressure valve (2). 5. Flow monitoring device for liquefied gas tank, according to any one of claims 1 to 4, CHARACTERIZED by the fact that the switch shaft (7), the switch spring (12), the switch handle ( 6) and the button rod (5) are coaxial. 6. Flow monitoring device for liquefied gas tank, according to claim 2, CHARACTERIZED by the fact that the switch handle (6) and the plug-in rod (6d) are integrally formed; the switch shaft (7), the first boss (7a) and the third stop block (7f) are integrally formed; the gas cylinder ring groove (8a), the fourth stop block (8b) and the gas inlet nozzle (8c) are integrally formed; the first support bar (9a), the second support bar (9b), the first fixing post (9c) and the first step (9d) are integrally formed; and the clamping ring (10a), the clamping slot (10b), the second clamping post (10c) and the upper post (10d) are integrally formed.

Images