KR20060038011A - Regulator valve for gas tank - Google Patents

Abstract

Disclosed is a gas valve which is installed in a gas reservoir and the like, as well as a control atmosphere for ensuring supply stability of gas and an open atmosphere for discharging residual gas.

Such a gas valve is provided between a reservoir and a supply hose in which gas is stored, and is a valve capable of switching not only the supply of gas but also a corresponding flow path at the time of filling,

A main regulator formed with a main flow passage connected to the discharge side of the gas reservoir, a pressure regulating portion formed with a control flow passage for discharging excess pressure inside the gas reservoir on the main flow passage of the main body, and a main flow path of the main flow passage; A discharge passage connected to the supply hose is formed and connected to the supply hose side, a control knob for opening and closing the main passage of the main body, and located on the main passage section of the main body when the gas is supplied or filled, the main passage A control unit installed to be switched to a blocked state or an open state, and magnetic force generating means for generating a magnetic force having different polarities from the outside of the main body so that the main flow path is opened by the control unit. do.

The control unit controls the opening and closing operation in a non-contact manner by the magnetic force inducing action of the magnetic force generating means outside the main body such that the inside of the main flow path becomes a flow path atmosphere for supplying or filling gas.

Valve body, gas reservoir, supply hose, main flow path, control unit with regulator function, pressure control unit, main flow path change by external magnetic force, gas filling, residual gas discharge

Description

Regulator valve for gas tank

1 is an overall perspective view showing a preferred embodiment of the gas valve according to the present invention.

2 is an overall cross-sectional view of FIG.

3 is a partially enlarged cross-sectional view for explaining the main structure of FIG.

4 is a partially enlarged cross-sectional view illustrating the structure of the discharge part of FIG. 2.

FIG. 5 is a partially enlarged cross-sectional view illustrating the control unit structure of FIG. 2.

6 is a perspective view for explaining the structure of the fixing member of FIG.

FIG. 7 is a partially enlarged cross-sectional view illustrating the operation of the controller of FIG. 2.

8 is a perspective view illustrating the structure of the ground plate of FIG. 5.

The present invention relates to a gas valve that can easily control the flow atmosphere of the flow path section to be an open atmosphere for the complete discharge of residual gas as well as a control atmosphere for ensuring the supply stability of the gas.

LP-GAS, which is generally used in homes and businesses, is a pressurized and liquefied petroleum gas such as butane and propane, which are gases at room temperature, at about 6 atmospheres to reduce volume and facilitate storage and transportation. After filling the inside of the gas reservoir is stored in a specific place outside the building, for example, it is connected to the supply hose so that the gas can be supplied to the kitchen and heating equipment, such as a gas range or gas heater.

At this time, the gas reservoir is provided with a valve that can ensure the maximum flow stability of the gas, the valve is provided on the discharge side of the reservoir is made to supply and control the gas.

Briefly describing the general structure of the gas valve, the main passage is formed to be connected to the discharge side of the gas reservoir containing a certain amount of gas, and to discharge the excess pressure inside the gas reservoir from the main passage of the main body A pressure regulating portion for forming an adjusting passage for forming the discharge passage, a discharge passage communicating with a direction crossing the main passage of the main body, a discharge portion connected to the hose side, and a regulating knob for opening and closing the main passage of the main body; And a control unit configured to be in a state in which a predetermined amount of gas can be supplied to the discharge part side through the main flow path from the main body.

The valve may include a flow path section in which the main flow path of the main body is opened and closed by the control knob, and the gas stored in the gas reservoir side can be supplied in a controllable state along the supply hose while passing through the main body and the discharge part. In this case, the control unit is configured to perform a kind of regulator function such that a predetermined amount of gas is always uniformly supplied to the discharge passage side of the discharge unit at the main passage side of the main body.

The control unit capable of the above operation is elastically fixed with a posture that provides a passage through which a single disk is provided by a disk-shaped elastic member having a constant elastic force on the main flow path section of the main body.

That is, the control unit of the above structure maintains the fixed posture of the disk elastically by the elastic repulsive force of the elastic member when the gas filled in the gas reservoir flows to the discharge part side via the main flow path at a constant pressure. Since the main flow passage section becomes a control atmosphere capable of preventing excessive discharge of gas, a certain amount of gas is always supplied to the discharge flow path side of the discharge portion by such an atmosphere.

In addition, the operation of the control unit as described above can prevent the gas is supplied excessively through the gas valve to prevent the safety accident according to this, in particular installed on the discharge portion and the pressure control side artificial manipulation from the outside Unlike the possible valves, the built-in structure installed inside the main body is not only operable from the outside, but also ensures the maximum flow stability of the gas valve even when a physical shock or vibration is applied from the outside. .

However, the above-described conventional gas valve is limited to a function of preventing the excessive supply of gas flowing while the control unit is installed on the main flow path section inside the main body and flows through this flow path. When the residual gas is removed from the filling station or the like to recharge the gas into the gas reservoir, a blocking atmosphere in which the main channel is always opened by the control unit at a constant area is maintained. There is a problem that takes time.

In addition, since the control unit is built in the main body and cannot be artificially opened and closed from the outside, it is difficult to expect satisfactory operability and work compatibility when recharging the gas, and particularly in the winter when the temperature is low, residual gas inside the gas reservoir Since they are in an inert atmosphere, there is a problem that the degassing efficiency as well as the recharging efficiency are further lowered.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is not only a control atmosphere for ensuring the supply stability of the gas, but in particular, to provide a flow path environment corresponding to the refilling operation of the gas It is to provide a gas valve that can obtain a satisfactory functionality and work compatibility.

In order to realize the object of the present invention as described above, the valve is installed between the reservoir and the supply hose for storing the gas, as well as the supply of gas, and can be switched to the flow path atmosphere corresponding to the filling,

A main regulator formed with a main flow passage connected to the discharge side of the gas reservoir, a pressure regulating portion formed with a control flow passage for discharging excess pressure inside the gas reservoir on the main flow passage of the main body, and a main flow path of the main flow passage; A discharge passage connected to the supply hose side is formed, and a discharge passage connected to the supply hose side, a control knob for opening and closing the main passage of the main body, and the main passage of the main passage located on the main passage section of the main body when the gas is supplied or filled A control unit installed to switch the flow path to a blocked state or an open state, and magnetic force generating means for generating a magnetic force having different polarities from the outside of the main body so that the main flow path can be opened by the control unit. It provides a gas valve comprising.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail.

1, 2, and 3, the gas valve according to the present invention includes a main body 2 having a main flow path L1 connected to a discharge side of a gas reservoir T in which gas is contained, and A pressure regulating unit 4 having a control passage L2 for discharging excessive pressure inside the gas reservoir T on the main passage L1 of the main body 2, and a main passage of the main body 2. A discharge part 6 in which the discharge flow path L3 communicating with L1 is formed, an adjustment knob 8 for opening and closing the main flow path L1 of the main body 2, and a main flow path of the main body 2; The control unit 10 is disposed on the section (L1) so that the main flow path (L1) can be switched to a cutoff state or an open state when the gas is supplied or charged, and has a different polarity outside the main body (2). Magnetic force generating means 12 for generating a magnetic force to open the main flow path (L1) by the control unit 10. Such a valve may be installed to enable the supply and control of gas in a manner well known on the discharge side of the gas reservoir T as shown in FIG. 1.

The main body 2 has a main flow path L1 formed therein as shown in FIG. 2 so as to supply gas in association with a pressure regulating part 4, a discharge part 6, and a regulating knob 8, which will be described later. The inflow side of the main flow path L1 is connected to the discharge side of the gas reservoir T in the state as shown in the drawing so as to enable gas supply and control.

The pressure regulator 4 has a relief valve function for adjusting an excessive pressure inside the gas reservoir T. For this purpose, the pressure regulator 4 corresponds to the main flow path L1 of the main body 2. Protruding and formed in the same direction as in 2, there is formed a control passage (L2) in communication with the main passage (L1) side.

The control passage (L2) is formed as shown in Figure 2 so as to communicate with the flow path (L1) between the main flow path (L1) section, the control flow path (L2) to control valve (V1) for discharging excess pressure Is installed.

The control valve (V1) is the control disk 14 and the coil spring 16 is as shown in the figure, that is, the control disk 14 by the elastic force of the coil spring 16, the control disk 14 of the control passage l2 The inflow side is set to be always in a closed state, and in such a state, when an excessive pressure is generated in the gas reservoir T and transmitted to the main flow path L1, the coil spring 16 is lifted in the direction in which the inlet side is closed. As the adjusting disk 14 moves, the adjusting passage L2 is opened to discharge excess pressure through the discharge side of the adjusting passage L2.

When the excess pressure is discharged, the adjustment disk 14 returns to the original position by the elastic force of the coil spring 16, and the adjustment flow path is prevented by the sealing ring 18 fixed to the adjustment disk 14. It is a well-known relief valve structure that blocks L2).

The discharge part 6 protrudes in the same direction as in FIG. 2 corresponding to the discharge side of the main body 2, that is, the main flow path L1, and has an discharge flow path communicating therewith with the main flow path L1. L3 is formed.

The flange portion of the supply hose (H) as shown in Figure 1 is connected to the discharge side of the discharge passage (L3), for example, although not shown in the drawing is connected to enable the gas supply to the indoor kitchen or heating appliances. At this time, the discharge valve (L2) is provided with a discharge valve (V2) for controlling the discharge of the gas.

The discharge valve (V2) is for controlling the discharge action of the gas supplied from the main flow path (L1) through the discharge flow path (L3), for this purpose inlet side of the discharge flow path (L3) as shown in FIG. In the valve seat 20 and the discharge disk 22, and comprises a coil spring (24).

The discharge disk 22 is set to be always in the closed state of the orifice of the valve seat 20 by the elastic force of the coil spring 24, in this state as shown in Figure 4 the supply hose (H) When the flange portion of the valve is inserted, the discharge disk 22 is moved in the direction in which the coil spring 24 is lifted by the physical contact with the flange portion while opening the orifice of the valve seat 20 to allow gas to flow into the discharge passage. It is to operate so that it can be supplied along the hose (H) through (L3).

That is, the discharge valve V2 is capable of discharging gas only when the supply hose H is fitted to the discharge part 6 side, and the discharge flow path L3 when the supply hose H is not fitted. ) To essentially prevent the gas from being discharged.

The adjusting knob 8 is for blocking or opening between the main flow path L1 and the discharge flow path L3 by a rotational movement on the main body 2 side. The screw shaft 26 and the guide shaft 28 which move up and down by the forward and reverse rotation of the knob 8 located therein, and the blocking disk 30 fixed to the end side of the guide shaft 28 are the main body ( 2) in the slide hole 32, as shown in Figure 2 may be a structure set as shown in the figure.

The guide shaft 28 is rotatably fixed to an end portion of the screw shaft 26 screwed with the slide hole 32 side, and when the knob 8 is rotated forward and backward, the guide shaft 28 is rotated along the screw shaft 26. While moving up and down, the blocking disk 30 is to block or open the discharge side of the main flow path (L1) as shown in FIG.

The adjustment knob 8 blocks or opens the main flow path L1 and flows from the main flow path L1 to the discharge flow path L3 regardless of the action of the discharge valve V1 of the discharge part 2. The supply of gas can be controlled.

The main body 2, the pressure control unit 4, the discharge unit 6, and the adjustment knob 8 is the same as the general structures already well known and used in the field according to the present invention in addition to the above-described structure. Or a similar structure.

On the other hand, the main flow path (L1) side of the main body (2) when switching the gas from the gas reservoir (T) to the discharge portion 6 side when switching the main flow path (L1) to the corresponding flow path atmosphere The control unit 10 is provided.

2 and 3, the control unit 10 has a housing 34 which provides a space for a control action at the main flow path L1, and is located in an internal space of the housing 34 and has a magnetic force response. The control disk 36 is enabled, a fixing member 38 for resiliently fixing the control disk 36 by the elastic force in the housing 34, and the control disk in the housing 34. Corresponding to 36 includes a ground plate 40 which is installed to enable mutual magnetic action.

The housing 34 is formed within a size range that can be fixed to the main passage (L1) by fitting coupling, for example, the inner side is formed with a space in the direction corresponding to the main passage (L1) section, ring ( RING) shape.

The housing 34 is firmly fixed to prevent the position set in the main flow path L1 from being changed or dislodged after being fitted to the main flow path L1 and the pressure of the gas.

The control disk 36 is installed in the fixing member 38, which will be described later in the space portion of the housing 34, a regulator valve in a blocking atmosphere so that a certain amount of gas flows to the discharge side of the main flow path L1 at all times. valve) function is enabled, and the main flow path L1 can be switched to a fully open atmosphere by an external magnetic induction action. To this end, the end of the control disk 35 as shown in Figure 3 so that the control disk 35 is mutually magnetic reaction with the ground plate 40 by the magnetic induction action of the magnetic force generating means 12 described later The auxiliary ground plate 42 is installed.

The auxiliary ground plate 42 is a ferromagnetic alloy that is magnetized when the magnetic force is generated in the magnetic force generating means 12 to smoothly induce mutual magnetic reaction with the ground plate 40 side.

The fixing member 38 is for elastically fixing the control disk 36 in the inner space of the housing 34, for this purpose has a predetermined thickness and holes 44 are formed as shown in FIG. For example, it has a structure like a leaf spring.

At this time, the holes 44 are fixed to the fixing member 380 in the posture as shown in FIG. 3 and the control disk 36 is elastically at the space side of the housing 34. It provides an elastic force that can be supported and provides a passage through which gas can flow.

The outer circumferential side of the fixing member 38 is fitted to the inner diameter side of the space portion of the housing 34, wherein the control disk 36 is the discharge side of the main flow path L1 in the space portion of the housing 34. The regulator is spaced apart in a corresponding range so that a regulator function capable of supplying a certain amount of gas can be provided corresponding to the end portion.

The ground plate 40 is the auxiliary ground plate of the control disk 36 by the magnetic force generating means 12 to be described later in a state in which the control disk 36 is installed in a posture capable of a regulator function on the housing 34 side. The main flow path L1 is induced to switch to an open atmosphere as shown in FIG. 7 while the mutual magnetic force is induced with the 42, and for this purpose, the control unit is formed in a disc shape having a constant thickness as shown in FIG. It has a posture facing the auxiliary ground plate 42 of the disk 36 and is installed in the housing 34 as shown in FIG.

As the material of the ground plate 40, a ferromagnetic alloy capable of being magnetized, such as the auxiliary ground plate 42, is used. The magnetic force generating means 12, which will be described later, is provided when installed on the space side of the housing 34. By pulling the auxiliary ground plate 42 by a magnetic force by the control disk 36 to which the auxiliary ground plate 42 is coupled can easily switch the discharge side of the main flow path (L1) into an open atmosphere. It is installed within a certain range.

In addition, the ground plate 40 is made of a structure that allows the smooth passage of the magnetic reaction with the auxiliary ground plate 42 side as well as the gas passes smoothly. For example, a plurality of holes 46 as shown in FIG. 8 are formed through the center plate and the outer peripheral surface side of the ground plate 40. In such a structure, the magnetic force may be concentrated in the circumferential direction between the center and the outer surface of the ground plate 40, so that a more smooth magnetic reaction and action may be made with the auxiliary ground plate 42.

The magnetic force generating means 12 generates an induction magnetic force capable of mutual magnetic reaction between the auxiliary ground plate 42 and the ground plate 40 of the control unit 10, that is, the control disk 36, outside the main body 2. As shown in FIG. 7, when electricity is supplied through the electricity supply unit 48, two magnetic bodies 50a and 50b having different polarities (N and S poles) are connected to the ground plate 40. It may have a structure formed as shown in the figure to correspond to the auxiliary ground plate 42.

As shown in FIG. 3, the means 12 may have different polarity examples by the electric supply unit 48 in a state in which the main passage 11 has an atmosphere in which a regulator function is possible by the control disk 36. As shown in FIG. For example, as shown in FIG. 7, the magnetic body 50a having the S pole and the magnetic body 50b having the N pole are located outside the main body 2 as shown in the drawing. The main flow path L1 is switched to the open atmosphere.

That is, the magnetic induction phenomenon is induced by the two magnetic bodies (50a, 50b) on the outside of the main body (2), which causes the auxiliary ground plate 42 and the ground plate 40 as shown in FIG. Since the auxiliary ground plate 42 adheres to the ground plate 40 side as shown in the drawing by magnetization in the form of a pole and an N pole, and a magnetic force reaction between them. By this action, the inside of the main flow path L1 is switched from the blocking atmosphere in which the regulator function is possible to the open atmosphere.

At this time, the induced magnetic force by the two magnetic bodies (50a, 50b) is made to be greater than the elastic force of the fixing member 38 for fixing the control disk (36). If an induction magnetic force smaller than the elastic force of the fixing member 38 is generated, the auxiliary ground plate 42 may not move smoothly by the elastic force of the fixing member 38, and thus the operability of the control disk 36 may be reduced. Is difficult to obtain.

Then, in order to switch back to the original blocking atmosphere in the open atmosphere of the main flow path L1 as described above, the main body 2 side is spaced apart from the magnetic force within the range of the magnetic force or the electricity supply unit 48 You can turn off.

The magnetic force generating means 12 having the above structure controls the operation of the controller 10 in a non-contact manner without using any physical contact force from the outside of the main body 2 so that the inside of the main flow path L1 is a regulator. The function can be easily switched to a blocking atmosphere or an open atmosphere.

In particular, the valve structure that can be easily switched to the atmosphere capable of fully opening the main flow path L1 by using the magnetic force generating means 12 as described above, the gas storage tank (T) side in the gas filling station, for example. Improved work compatibility and efficiency can be obtained upon release of residual gas, which is done before gas filling.

In the above embodiment, the magnetic force generating means 12 is an electromagnet structure in which the two magnetic bodies 50a and 50b have different polarities due to electricity supply, but are not limited thereto.

For example, the two magnetic bodies (50a, 50b) is made of a well-known permanent magnet already generates a magnetic force smoothly from the outside of the main body (2) without performing a separate electric supply, the main in the non-contact manner as described above The controller 10 may be set to easily control the control unit 10 installed in the flow path L1.

In the above, a preferred embodiment of the gas valve according to the present invention has been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. This also belongs to the scope of the present invention.

As described above, the present invention not only has a blocking atmosphere in which the flow path section inside the valve body can be uniformly supplied at all times while preventing excessive discharge of gas by the controller, and in this state, the channel is completely opened by the magnetic force generating means. Easily switchable to this possible atmosphere can further improve the control efficiency and functionality of the valve.

In addition, the magnetic force generating means is a non-contact type outside of the main body of the control unit installed on the flow path section inside the main body by the magnetic induction action using two permanent magnets or electromagnet type magnetic material having different polarity The physical control can be performed easily, and in particular, such a structure can provide more improved operability and work compatibility when the residual gas is discharged before the gas is refilled in the gas reservoir at the filling station or the like.

Claims (6)

The valve is installed between the reservoir and the supply hose to store the gas and can be switched not only to supply gas but also to the flow path atmosphere at the time of filling, A main regulator formed with a main flow passage connected to the discharge side of the gas reservoir, a pressure regulating portion formed with a control flow passage for discharging excess pressure inside the gas reservoir on the main flow passage of the main body, and a main flow path of the main flow passage; A discharge passage connected to the supply hose is formed and connected to the supply hose side, a control knob for opening and closing the main passage of the main body, and located on the main passage section of the main body when the gas is supplied or filled, the main passage A control unit installed to be switched to a blocked state or an open state, and magnetic force generating means for generating a magnetic force having different polarities from the outside of the main body so that the main flow path is opened by the control unit. Gas valve. The control unit of claim 1, wherein the control unit comprises: a housing for providing a space for a control action on the main flow path side of the main body, a control disk positioned in an inner space of the housing and capable of a magnetic reaction; A gas valve comprising a fixing member for resiliently fixing by an elastic force therein, and a ground plate installed in the housing so as to mutually act in response to the control disk. The gas valve according to claim 2, wherein the control disc and the ground plate are partially or entirely made of a ferromagnetic metal so as to enable magnetic force induction and reaction by the magnetic force generating means therebetween. The gas valve according to claim 2, wherein the control disk switches the main channel of the main body to a blocking atmosphere or an open atmosphere while being attached to or spaced apart from the ground plate side by a magnetic force reaction inside the housing. The gas valve according to claim 1, wherein the magnetic force generating means comprises two magnetic bodies having different polarities. The gas valve of claim 5, wherein the magnetic material is made of an electromagnet or a permanent magnet.

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