GRAPHENE HEATER FOR OIL TANK OF OIL FIELD

Abstract

Disclosed is a graphene heater for an oil tank of an oil field. A heating layer of the heater is a graphene layer (2); a high-temperature-resistant insulating layer (1), an intermediate layer composed of the graphene layer (2) and electrode layers (3), and a high-temperature-resistant insulating layer (1) are tightly attached together in sequence and then attached to an inner wall of a housing (5); the housing (5) is columnar; one end of the housing (5) mounted in the oil tank is closed; the other end of the housing is fixed on a surface of the oil tank by means of a flange plate (4); the flange plate (4) of the housing (5) is partially connected to a junction box (8); and when the electrode layers (3) at two ends of the graphene layer (2) are powered on, under the action of an electric field, heat energy generated by severe friction and impact between carbon atoms of graphene is radiated by means of far infrared ray with a wavelength of 5 to 14 microns, so that heat is effectively provided, so as to realize heating, heat preservation and freezing prevention of the oil tank of the oil field.

Claims

1. A graphene heater for an oil tank of an oil field, comprising a flange plate, a housing, a high-temperature-resistant insulating layer, a heating layer, electrode layers and a high-temperature-resistant wire, wherein the heating layer is a graphene layer.

2. The graphene heater for the oil tank of the oil field according to claim 1, wherein the high-temperature-resistant insulating layer, the graphene layer and the electrode layers, and the high-temperature-resistant insulating layer are tightly attached together in sequence and then attached to an inner wall of a housing.

3. The graphene heater for the oil tank of the oil field according to claim 1, wherein the housing is columnar; one end of the housing is closed; the other end of the housing is fixed on a surface of the oil tank by the flange plate; and the flange plate of the housing is partially connected to a junction box.

4. The graphene heater for the oil tank of the oil field according to claim 2, wherein one side of a high-temperature-resistant insulating sheet having the same cross-sectional shape as that of an inner cavity of the housing is clung to an inner surface of the closed end of the housing and covers the entire inner surface of the closed end of the housing; and at both ends, planes, perpendicular to an axis of the housing, of a perforated high-temperature-resistant insulating sheet and the high-temperature-resistant insulating sheet having the same cross-sectional shape as that of the inner cavity of the housing are clung to end faces, perpendicular to the axis of the housing, of a portion composed of attaching the high-temperature-resistant insulating layer, the graphene layer and the electrode layers, and the high-temperature-resistant insulating layer in sequence.

5. The graphene heater for the oil tank of the oil field according to claim 3, wherein a barrel-shaped portion of one end of the junction box is plugged into the housing; and a cross section of an outer diameter of the barrel-shaped portion of the junction box plugged into the housing has the same shape as that of the cross section of the inner cavity of the housing.

6. A graphene heater for an oil tank of an oil field, comprising: a cylindrical housing, wherein one end of the housing is closed and is plugged into the oil tank, and the other end of the housing is provided with a flange plate and is fixed on a surface of the oil tank; an attachment structure attached to an inner wall of the housing, wherein the attachment structure comprises a first high-temperature-resistant insulating layer, an intermediate layer and a second high-temperature-resistant insulating layer which are attached and connected in sequence; the intermediate layer comprises a graphene layer and electrode layers located at two ends of the graphene layer; the electrode layers are connected with high-temperature-resistant wires; a high-temperature-resistant insulating sheet having the same cross-sectional shape as that of the inner cavity of the housing, wherein the high-temperature-resistant insulating sheet is clung to and covers the entire inner surface of the closed end of the housing; a perforated high-temperature-resistant insulating sheet having the same cross-sectional shape as that of the inner cavity of the housing; and a junction box connected with the flange plate; wherein the perforated high-temperature-resistant insulating sheet and the high-temperature-resistant insulating sheet are respectively clung to two end faces of the attachment structure; and the end faces are perpendicular to an axis of the housing.

7. The graphene heater for the oil tank of the oil field according to claim 6, further comprising a temperature sensing probe, wherein the temperature sensing probe is used for detecting a temperature of an inner surface of the first high-temperature-resistant insulating layer or the second high-temperature-resistant insulating layer; and the temperature sensing probe is connected with a temperature sensing probe connection wire.

8. The graphene heater for the oil tank of the oil field according to claim 7, further comprising an explosion-proof temperature controller, explosion-proof wire connectors and a power supply, wherein the temperature sensing probe is connected to the explosion-proof temperature controller; the high-temperature-resistant wire is connected to the explosion-proof wire connector; wires led from the explosion-proof wire connectors are connected to the explosion-proof temperature controller; and the wires led from the explosion-proof temperature controller is connected to the power supply.

9. The graphene heater for the oil tank of the oil field according to claim 6, wherein one end of the junction box is a barrel-shaped portion; the barrel-shaped portion is plugged into the housing; and a cross section of an outer diameter of the barrel-shaped portion has the same shape as that of the cross section of the inner cavity of the housing.

10. The graphene heater for the oil tank of the oil field according to claim 3, wherein one side of a high-temperature-resistant insulating sheet having the same cross-sectional shape as that of an inner cavity of the housing is clung to an inner surface of the closed end of the housing and covers the entire inner surface of the closed end of the housing; and at both ends, planes, perpendicular to an axis of the housing, of a perforated high-temperature-resistant insulating sheet and the high-temperature-resistant insulating sheet having the same cross-sectional shape as that of the inner cavity of the housing are clung to end faces, perpendicular to the axis of the housing, of a portion composed of attaching the high-temperature-resistant insulating layer, the graphene layer and the electrode layers, and the high-temperature-resistant insulating layer in sequence.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] FIG. 1 is a three-dimensional diagram of an embodiment of the present disclosure, in which a fastener for fixing a flange plate, and a sealing washer are omitted.

[0009] FIG. 2 is a schematic diagram of a relative position between materials that constitute a graphene heater for an oil tank of an oil field and a sealed end of a housing in an embodiment of the present disclosure, in which a fastener for fixing a flange plate, and a temperature sensing probe connection wire and high-temperature-resistant wires led from wire outlet holes are omitted.

[0010] FIG. 3 is a schematic diagram of wire outlet holes on a junction box in an embodiment of the present disclosure.

[0011] FIG. 4 is a schematic diagram of a state of mounting a graphene heater for an oil tank of an oil field in an oil tank and a working principle, in which other structures of the oil tank, crude oil in the oil tank and a fastener for mounting a flange plate of the graphene heater for an oil tank of an oil field.

[0012] In the drawings: 1: high-temperature-resistant insulating layer; 2: graphene layer; 3: electrode layer; 4: flange plate; 5: housing; 6: high-temperature-resistant wire; 7: temperature sensing probe; 8: junction box; 9: wire outlet hole; 10: sealing washer; 11: high-temperature-resistant insulating sheet; 12: perforated high-temperature-resistant insulating sheet; 13: oil tank; 14: support; 15: wire; 16: temperature sensing probe connection wire; 17: explosion-proof wire connector; 18: explosion-proof temperature controller; 19: power supply; and 20: graphene heater for an oil tank of the oil field.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0013] The present disclosure is described in detail in combination with the accompanying drawings and embodiments of this specification.

Embodiment

[0014] As shown in FIG. 1, a housing (5) of a graphene heater for an oil tank of an oil field is cylindrical, and a flange plate (4) of the housing (5) is partially connected with a junction box (8).

[0015] As shown in FIG. 2, one end of the housing (5) of the graphene heater for an oil tank of an oil field plugged in an oil tank (13) is closed; the other end of the housing (5) is used for fixing the graphene heater for an oil tank of an oil field on a flange plate (4) on a surface of the oil tank (13); the flange plate (4) is connected to the junction box (8); a high-temperature-resistant insulating layer (1), a graphene layer (2) and electrode layers (3), and a high-temperature-resistant insulating layer (1) of the graphene heater for an oil tank of an oil field are attached together in sequence, and are then attached to an inner wall of the housing (5); one side of a high-temperature-resistant insulating sheet (11) having the same cross-sectional shape as that of an inner cavity of the housing (5) is clung to an inner surface of the closed end of the housing (5) and covers the entire inner surface of the closed end of the housing (5); and at both ends, planes, perpendicular to an axis of the housing (5), of a perforated high-temperature-resistant insulating sheet (12) and the high-temperature-resistant insulating sheet (11) having the same cross-sectional shape as that of the inner cavity of the housing (5) are clung to end faces, perpendicular to the axis of the housing (5), of a portion composed of attaching the high-temperature-resistant insulating layer (1), the graphene layer (2) and the electrode layers (3), and the high-temperature-resistant insulating layer (1) in sequence, thus forming insulated isolation; a temperature sensing probe connection wire (16) connected with a temperature sensing probe (7) and high-temperature-resistant wires (6) respectively connected with the electrode layers (3) at the two ends of the graphene layer (2) are respectively led to the junction box (8) and are then led out from three wire outlet holes (9) of the junction box (8) (in the figure, the temperature sensing probe connection wire (16) and the high-temperature-resistant wires (6) led from the wire outlet holes are omitted); a sealing washer (10) prevents crude oil in the oil tank from leaking when a fastener for the flange plate of the graphene heater for an oil tank of an oil field is mounted and fixed on a surface of the oil tank.

[0016] As shown in FIG. 3, a structure of the junction box (8) provided with three wire outlet holes (9).

[0017] As shown in FIG. 4, the graphene heater (20) of an oil tank of the oil field is mounted on a support (14) at an inner bottom of a cavity of the oil tank (13); one end of the graphene heater (20) of an oil tank of the oil field is fixed on a surface of the oil tank (13) by the flange plate (4) and a fastener; the temperature sensing probe connection wire (16) led from a temperature sensing probe (7) is connected to an explosion-proof temperature controller (18); the high-temperature-resistant wires (6) led from the electrode layers (3) at the two ends of the graphene layer (2) are respectively connected to explosion-proof wire connectors (17); wires (15) led from the explosion-proof wire connectors (17) are connected to a temperature controller (18); and the wires (15) led from the temperature controller (18) are connected to a power supply (19).

[0018] When the electrode layers (3) at the two ends of the graphene layer (2) are connected to the power supply (19), under the action of an electric field, heat energy continuously generated by severe friction and impact between carbon atoms of the graphene layer (2) is uniformly radiated in the form of a plane by means of far infrared ray with a wavelength of 5 to 14 microns, so that heat is directly transferred to an inner surface of the housing (5) of the graphene heater for an oil tank of an oil field, and the temperature of the housing (5) of the graphene heater for an oil tank of an oil field continuously rises from inside to outside; and the housing (5) of the graphene heater for an oil tank of an oil field continuously transfers the heat to the crude oil in the oil tank. The temperature sensing probe (7) continuously transfers the temperature of the inner surface of the high-temperature-resistant insulating layer (1) of the graphene heater for an oil tank of an oil field to the explosion-proof temperature controller (18) through the temperature sensing probe connection wires (16). When the temperature of the inner surface of the high-temperature-resistant insulating layer (1) of the graphene heater for an oil tank of an oil field reaches a temperature preset by the explosion-proof temperature controller (18), the explosion-proof temperature controller (18) automatically switches off circuits of the electrode layers (3). At this time, the graphene layer (2) stops radiating the far infrared ray, and the temperature of the outer surface of the housing (5) of the graphene heater for an oil tank of an oil field starts to decrease. When the explosion-proof temperature controller (18) detects through the temperature sensing probe (7) that the temperature of the inner surface of the high-temperature-resistant insulating layer (1) of the graphene heater for an oil tank of an oil field is less than the temperature preset by the explosion-proof temperature controller (18), the explosion-proof temperature controller (18) automatically switches on the circuits of the electrode layers (3). Under the action of the electric field, the graphene layer (2) starts to radiate far infrared ray again to heat the housing (5) of the graphene heater for an oil tank of an oil field. The above processes are repeated to achieve continuous work, which effectively meets the demands for heating and thermal insulation of the oil tank of the oil field and achieves the effect of saving energy.