JPH1061507A - Mounting structure of additive filling pipe for fossil fuel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve combustion efficiency by efficiently mixing minute amount of additive in the whole large amount of fossil fuel and suppressing the degradation of fossil fuel as much as possible and prevent a lowering of rigidity of an oil feed pipe and a liquid leakage. SOLUTION: On the tip side of an additive filling pipe 8, an axial slitting groove 8a is formed, leaving the tip part. The slitting groove 8a and the additive supply passage on the inside of the additive filling pipe are communicated. On the outer periphery of the back side of the additive filling pipe 8, a male screw 8b is provided. A female screw hole 6a is drilled in an oil feed pipe 6, the tip side of the additive filling pipe 8 is inserted into the female screw hole 6a and the male screw 8b of the additive filling pipe 8 is screwed in the female screw hole 6a of the oil feed pipe 6. The tip of the additive filling pipe 8 is in press-contact with the wall opposed to the oil feed pipe 6 by the screw-in of the male screw 8a, a swelling deformation to the both sides of the slitting groove 8a is performed for the tip side of the additive filling pipe 8, both of swelling deformation parts 8c and 8c are arranged in the orthogonal direction of flow of heavy oil and the additive filling pipe 8 is mounted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to gasoline, light oil, heavy oil, etc., which are used as fuel for boilers and engines of fuel systems of ships, airplanes, railway vehicles, automobiles and various power machines, including air conditioning equipment, and other power machines. The present invention relates to a structure in which a fossil fuel additive injection pipe for injecting an additive for promoting combustion into a fossil fuel is attached to an oil supply pipe.

[0002]

2. Description of the Related Art In air conditioning equipment such as buildings, heavy oil used as fuel for boilers is stored in a large main tank installed in the ground or in a basement, and the required amount is reduced to a small service. Once pumped into a tank, it is sent to a boiler combustor. In this way, the heavy oil stored in the main tank deteriorates with the passage of the storage days and the combustion efficiency decreases, incombustibles remain in the combustor as sludge, and harmful substances such as nitrogen oxides and sulfur oxides are removed. Mixing an additive that aids combustion with fuel heavy oil is useful for suppressing the deterioration of fuel oil and improving combustion efficiency, as it causes black smoke and odor. Is extremely small, it was extremely difficult to mix the additive into the entire heavy oil if the additive was directly added to the heavy oil in the main tank or the service tank.

For this reason, in the air conditioning equipment, a T-shaped pipe is interposed in an oil supply pipe connecting the main tank and the service tank, and an additive is injected into the supply pipe through an opening of the T-shaped pipe projecting sideways. Thus, a quantity of additive corresponding to the flow rate of heavy oil in the oil supply pipe is mixed using the flow of heavy oil.

[0004]

However, the additive to the flow rate of the heavy oil is about 1/5000, that is, when the flow rate of the heavy oil is 500 L for 1 minute, the additive is 100 m.
Due to the extremely small amount of L, it is still difficult to mix the additive with a large amount of heavy oil in the above-described configuration in which the additive is injected through a T-tube, and further improvement has been desired. Further, since the above-mentioned T-shaped pipe is interposed by dividing the oil supply pipe, the rigidity of the oil supply pipe is reduced, and the joint between the oil supply pipe and the T-shaped pipe causes liquid leakage, which is not preferable.

The present invention has been made in view of such circumstances, and has as its object to reduce the rigidity of a fuel supply pipe and to prevent liquid leakage, and to use a small amount of additive to a large amount of fossil fuel as a whole. It is an object of the present invention to provide a mounting structure for a fossil fuel additive injection pipe that can mix efficiently and suppress deterioration of a fossil fuel as much as possible to enhance combustion efficiency.

[0006]

SUMMARY OF THE INVENTION In accordance with the above objects, the present invention provides a fuel supply pipe for connecting a tank for storing fossil fuels such as gasoline, light oil, heavy oil, and a combustor for burning fossil fuels. A fossil fuel additive injection pipe mounting structure for mounting an additive injection pipe for injecting an additive into a fossil fuel, wherein an axial slit groove is provided at a tip side of the additive injection pipe except for a tip portion. Is formed, and the slit groove communicates with the additive supply passage inside the additive injection pipe, and a screw is provided on the outer periphery of the rear side of the additive injection pipe, and the oil supply pipe is provided at the mounting position of the additive injection pipe. By drilling a female screw hole, inserting the distal end of the additive injection pipe into the female screw hole, and screwing the external thread of the additive injection pipe into the female screw hole of the oil supply pipe, the tip of the additive injection pipe is removed. To the opposing wall of the oil supply pipe, and slide the tip end of the additive injection pipe. Ri and sides to bulging deformation of the groove, has a bulging deformation of both, characterized in that the mounting of the additive injection tube disposed in the orthogonal direction of the fossil fuel stream.

[0007] Since the bulging portion of the additive injection pipe is located perpendicular to the flow of the fossil fuel inside the fuel supply pipe, the contact area with the fossil fuel is significantly increased as compared with the conventional art, and a large area is formed downstream. Generates turbulence. The additive is injected into the fossil fuel from between the bulging portions through the additive supply passage inside the additive injection pipe, and is efficiently mixed with the fossil fuel by a large turbulent flow downstream of the bulging portion. Be matched.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the present invention is applied to a fuel system of an air conditioner used for a building such as a building will be described below with reference to the drawings. A fuel system 1 for an air conditioner shown in FIG. 2 includes a large main tank 2 for storing a large amount of heavy oil underground or in a basement, and a pump 3 from the main tank 2.
A small service tank 4 for temporarily storing a small amount of heavy oil pumped up by the fuel tank, and a combustor 5 for burning heavy oil supplied from the service tank 4 to operate a boiler (not shown).

The main tank 2 and the service tank 4 are connected by a first oil supply pipe 6, and the service tank 4 and the combustor 5 are connected by a second oil supply pipe 7. Is provided with an additive injection tube 8. The additive injection pipe 8 is provided with an axial slit groove 8a on the front end side and a screw 8b on the outer periphery on the rear side, and the additive injection pipe 8 is provided at the rear end of the additive injection pipe 8. A supply pipe 10 for connecting a liquid additive and an additive reservoir 9 for storing a liquid additive is provided with a fastener 11.
Are connected using.

The slot 8a is a wide oval hole formed between the additive injection pipe 8 and the screw 8b while leaving the tip of the additive injection pipe 8, and is formed inside the injection pipe at the end on the male screw side. A supply passage (not shown) is opened, and a lock nut 12 and a seal member 13 are mounted on the male screw 8b.

At a predetermined position of the first oil supply pipe 6 to which the additive injection pipe 8 is attached, a female screw hole 6a is bored toward the center of the first oil supply pipe 6, and Screw 8b
Is longer than at least the female screw hole 6a, and the length including the entirety of the external thread 8b from the tip of the additive injection pipe 8 is determined by the inner diameter of the first oil supply pipe 6 and the thickness of the first oil supply pipe 6. It is set longer than the added length. In addition, since the front end side of the additive injection pipe 8 sandwiching the slit 8a is deformed outward by pressing against the first oil supply pipe 6, the additive injection pipe 8 is more deformed than the first oil supply pipe 6. A soft metal material is used.

The additive reservoir 9 is provided with a liquid level gauge 9a. Above the additive reservoir 9, an additive inlet 9b and a pump 14 are provided. The pump 14 of the additive reservoir 9 is set to operate in synchronization with the pump 3 of the main tank 2, and the liquid additive stored in the additive reservoir 9 is such that the heavy oil in the main tank 2 When the oil is supplied to the service tank 4, an amount corresponding to the flow rate of the heavy oil flowing through the first oil supply pipe 6 is pumped up by the pump 14, and the slot 8a is supplied from the supply pipe 10 through the supply passage inside the additive injection pipe. To be poured out.

[0013] The additive injection tube 8 has a first oil supply tube 6 at the tip end.
Insert the female screw 8b into the female screw hole 6a.
Screwed in. Since the first oil supply pipe 6 and the additive injection pipe 8 have the above-described lengths, the additive injection pipe 8
Abuts against the opposite wall of the oil supply pipe 6 during the screwing of the male screw 8b, and the screwing of the additive injection pipe 8 is restricted.
Next, when the external thread 8b of the additive injection pipe 8 is further tightened, the reaction force from the opposing wall of the oil supply pipe 6 causes the slit groove 8a.
Of the additive injection pipe 8 whose rigidity is reduced due to the formation of the additive injection pipe 8, the both ends of the distal end side are bent from the middle part to the outside of the slit groove 8 a in a “<” shape, and the additive injection is performed. Both ends on the distal end side of the tube 8 are deformed into rhombic shapes as bulging deformation portions 8c.

Then, the bulging deformed portion 8c deformed into a rhombus,
8c is oriented in the direction perpendicular to the flow of the heavy oil, and then the lock nut 12 is screwed in the direction of the first oil supply pipe 6 to sandwich the seal material 13 between the lock nut 12 and the first oil supply pipe 6, thereby forming the seal. The additive injection pipe 8 is fixed to the first oil supply pipe 6 by tightening the lock nut 12 while sealing the space between the screw 8 b and the female screw hole 6 a with the material 13 in a liquid-tight manner.

As described above, the additive injection pipe 8 attached to the first oil supply pipe 6 has the first oil supply pipe 6 on both sides on the tip side.
Swelling deformation portion 8c larger than additive injection pipe 8 inside
8c, the contact area of the first oil supply pipe 6 with heavy oil flowing to the service tank 4 is significantly increased, and a complicated and large turbulent flow is generated downstream. As a result, the additive poured out from the supply passage of the additive injection pipe 8 into the slit 8a is drawn by the flow of the heavy oil hitting the bulging deformation portions 8c, 8c, and is downstream of the bulging deformation portions 8c, 8c. Get into turbulence,
After being mixed intricately with the entire heavy oil, it is supplied to the service tank 4.

In this embodiment, as described above, the complicated turbulent flow of heavy oil is generated downstream by the large bulging deformation portions 8c, 8c of the additive injection pipe 8, and the turbulent flow causes the heavy oil to flow out of the additive reservoir 9. Since the additive is mixed with the whole heavy oil, the additive is directly added to the main tank 2 or the service tank 4 or the additive is mixed by interposing a separate T-tube in the first oil supply pipe 6. As compared with the above, a small amount of additives can be efficiently mixed into a large amount of heavy oil as a whole, and the deterioration of heavy oil can be suppressed as much as possible, and the combustion efficiency can be effectively increased.

In addition, the bulging deformed portions 8c, 8c that generate a complicated turbulent flow in the heavy oil in the first oil supply pipe 6 are connected to the external threads 6a of the additive injection pipe 8 and the female oil pipe 6 to the first oil supply pipe 6. Screw hole 6a
Since it is formed into a large rhombus simply by screwing it in, the number of assembly steps and the number of parts can be reduced, and workability and economy can be improved. In addition, since the first oil supply pipe 6 is not divided when the additive injection pipe 8 is attached, the rigidity of the first oil supply pipe 6 does not need to be reduced, and the first oil supply pipe 6 has no joint, so that there is no fear of liquid leakage. .

In the above-described embodiment, the swelling deformation portion of the additive injection tube is described as a rhombus. However, depending on the material of the additive injection tube and the shape of the slit groove, it may be deformed into an arc shape or a waveform. Is also possible. In addition, the present invention can be applied to ships, aircraft, railway vehicles, automobiles,
It can be widely applied to fuel systems of various power machines. Among them, in a structure having no service tank, such as an air conditioner, an additive injection pipe is attached to an oil supply pipe connecting the storage tank and the combustor.

[0019]

As described above, the mounting structure of the fossil fuel additive injection pipe according to the present invention has an axial slit formed on the distal end side of the additive injection pipe except for the distal end. ,
The slit feed groove communicates with the additive supply passage inside the additive injection pipe, and a thread is provided on the outer periphery of the rear side of the additive injection pipe to supply fossil fuel to the combustor. A female screw hole is drilled at the mounting position, the tip side of the additive injection pipe is inserted into the female screw hole, and the external thread of the additive injection pipe is screwed into the female screw hole of the oil supply pipe, whereby the additive is injected. The tip of the pipe is pressed against the opposing wall of the oil supply pipe, and the tip of the additive injection pipe swells and deforms to both sides of the slit groove. By adding the additive injection pipe, the additive is mixed into the complicated turbulent flow of fossil fuel generated downstream of the bulging deformation part, so that a small amount of additive is efficiently mixed with a large amount of fossil fuel as a whole To minimize fossil fuel degradation and increase combustion efficiency effectively It becomes possible way.

Further, the bulging portion of the additive injection pipe which generates a complicated turbulent flow in the fossil fuel in the oil supply pipe can be formed by merely screwing the external thread of the additive injection pipe into the female screw hole of the oil supply pipe. Since it can be formed by extremely simple work, the number of assembly steps and the number of parts can be reduced, and workability and economy can be improved. In addition, since the oil supply pipe is not divided for mounting the additive injection pipe, the rigidity of the oil supply pipe does not need to be reduced, and there is no fear of liquid leakage since the oil supply pipe has no joint.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing a state in which an additive injection pipe according to an embodiment of the present invention is attached to an oil supply pipe.

FIG. 2 is a schematic diagram of a fuel system for an air conditioner showing one embodiment of the present invention.

FIG. 3 is an explanatory view showing an embodiment of the present invention before an additive injection pipe is attached to an oil supply pipe.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Fuel system for air conditioning equipment 2 ... Main tank 3, 14 ... Pump 4 ... Service tank 5 ... Combustor 6 ... 1st connecting main tank 2 and service tank 4
Oil supply pipe 6a Female thread hole 7 Second oil supply pipe connecting service tank 4 and combustor 5 8 Additive injection pipe 8a Slot groove 8b Male screw 8c Swelling deformed part 9 Additive storage 10 ... supply pipe 12 ... lock nut 13 ... sealing material

Claims (1)

[Claims] An additive injection pipe for injecting an additive for promoting fossil fuel combustion into an oil supply pipe connecting a tank for storing fossil fuels such as gasoline, light oil, heavy oil, and a combustor for burning fossil fuels. A mounting structure for a fossil fuel additive injection pipe to be attached, wherein an axial slit is formed at a distal end side of the additive injection pipe except for a tip portion, and the slit and the additive injection pipe are formed. In addition to communicating with the internal additive supply passage, a screw is provided on the outer periphery of the rear side of the additive injection pipe, and a female screw hole is drilled at a position where the additive injection pipe is attached to the oil supply pipe. The tip of the additive injection tube is inserted, and the external thread of the additive injection tube is screwed into the female screw hole of the oil supply tube. The tip end of the injection tube swells and deforms to both sides of the slit groove. Characterized in that the fuel injection valve is disposed in the direction perpendicular to the flow of the fossil fuel and the additive injection pipe is mounted.