RU2441781C1 - Motor cleaning device - Google Patents

Abstract

FIELD: automobile industry. ^ SUBSTANCE: this invention is designed for cleaning of the vehicle motors during their repair and maintenance, specifically for cleaning of oil channels, cooling liquid channels and complex geometry parts. The motor cleaning device includes a case with an end-to-end channel, which extends in its front portion, and a taper located in it, pipe installed coaxially to the channel and handle with pinned lever and valve. Additionally the device is equipped with carbon dioxide feed pipe and cavitation generator with jet in the form of a sand-glass which contracting diameter is calculated under the formula. ^ EFFECT: increase of purification quality due to enhancement of a cleaning jet with simultaneous decrease of labor and energy input of the cleaning process. ^ 4 cl, 2 dwg

Description

The invention is intended for cleaning vehicle engines during repair and maintenance, namely for cleaning oil channels, channels for coolant and parts of complex geometric shapes. The device can be used at large repair facilities and in small repair shops. With it, you can clean the channels and surfaces of complex geometric design from scale, corrosion products, carbon deposits, oily deposits.

A device for removing contaminants from deaf channels by introducing emitters into the treatment zone, consisting of: a waveguide, a diaphragm, magnetostrictive bags, a housing, a nozzle for supplying washing liquid, an oil seal, a gasket and a trigger switch [Book: L. D. Rozenberg. "Physics and technology of powerful ultrasound." Volume 3. M.: Publishing House of the Academy of Sciences of the USSR, 1970].

However, this device is not effective enough, since it does not provide complete removal of oil contaminants, while it requires the supply of additional electrical energy.

The closest in technical essence is the design for cleaning vehicles, comprising a housing with a through channel expanding in front of the channel and a cone located therein, facing a vertex inside the body, a tube mounted coaxially to the through channel, one cone fixed in the body, and a handle pivotally mounted on her lever and spool [certificate on PM No. 15469, MKL 7 B60S 1/00 2000].

A disadvantage of the known design is the impossibility of cleaning deaf channels of small diameter and surfaces of complex geometric shapes from oil-containing contaminants.

The problem to which the invention is directed, and the technical result of its use are associated with improving the quality of cleaning by increasing the energy of the jet while reducing the energy intensity and complexity of the cleaning process.

The technical result from the use of the invention is to improve the quality of cleaning due to the possibility of the formation of granules of carbon dioxide and cavitation bubbles, endowed with cleaning energy, which allows you to effectively remove tightly bound contaminants.

The technical result is achieved in that in a device for cleaning engines, comprising a housing with a through passage extending in the front part of the channel and a cone located therein, facing a vertex inside the housing, a tube mounted coaxially to the through passage channel, fixed at one end in the housing, and a handle pivotally mounted on with a lever and a spool, an additional tube and a cavitation generator connected with it are installed, having a narrowing part, determined by the formula:

d _to , D ₀ - respectively, the diameters at the critical section of the channel and at the outlet of the injector;

P ₀ , P ₂ - respectively, the pressure at the outlet and at the inlet to the injector;

To _s , K _h - respectively, the total coefficient of hydraulic losses and the coefficient of hydraulic losses for the narrowing channel;

R is the radius of the cavitation particle, which determines the depth of its penetration into the pollution particle.

It is advisable to present the cavitation generator in the form of a replaceable nozzle in the channel of the tube having a thread on the outer surface, with an injector located inside it and an additional tube connected for supplying carbon dioxide.

Preferably, the injector is made in the form of an hourglass-shaped cavity with a certain narrowing hole corresponding to d _k .

It is necessary to replace the nozzles with an external thread.

Justification of the diameter of the injector of the cavitation generator by the example of leakage of fluid through a flat curved section of figure 1.

From the Bernoulli equation, the pressure change in section 0-1 will be equal to:

P ₀ , P ₂ - respectively, the pressure at the outlet and at the inlet to the injector; MPa;

ρ is the density of the liquid, kg / m ³ ;

Δh _OB - total pressure loss in the injector, Pa;

V ₀ , V ₂ - respectively, the fluid velocity at the outlet and at the inlet of the injector, m / s.

We transform the expression (1), we get:

To _Z - the total coefficient of hydraulic losses in the injector;

C _X - injector drag coefficient

K _З = ξ _с + ξ _р + ξ _к

ξ _с - coefficient of hydraulic losses for narrowing;

ξ _p - resistance coefficient for expansion;

ξ _к - resistance coefficient in the critical part of the channel.

We assume that K _H = 1 + ξ _to

To _H - the coefficient of hydraulic losses for the narrowing channel.

According to the formula of G.V.Logvinovich, the diameter of the mid-section of the resulting cavity is determined by the formula:

d _{to the} diameter of the critical section of the injector, m;

k is the coefficient of proportionality, which depends on the pressure difference and on the area of the mid-section of the cavitation bubble;

σ is the local cavitation number of the flow.

Assuming that D _K = 2R, we determine the required radius of the resulting cavity, we obtain

D ₀ - diameter at the outlet of the injector, m

Having transformed, we get

Figure 2 shows a device for cleaning internal combustion engines.

A device for cleaning vehicle engines consists of a housing 1 with a through expanding channel 2, in which there is a cone 4, facing its apex inside the housing, and a tube 3. The cone 4 is fixed by a thread on the tube 3 and fixed from the end by a frame 6 with screws 7, which it has six holes located around the circumference, between the body 1 and the frame 6, a gasket 5 is installed. Inside the tube 3, a cavitation generator 8 is installed on the thread 8. Inside the cavitation generator there is an injector 10 having the form of sand hours with a diameter of the narrowed hole corresponding to d ₀ . In the body of the housing 1 is installed a tube 9 for supplying carbon dioxide, in communication with the tube 3.

Under the housing 1 is a handle 17 in which two channels A and B are made for supplying a washing liquid. Moreover, channel A is in communication with channel 2, and channel B with tube 3. Between the handle 17 and the housing 1 there is a sealing gasket 19 and they are interconnected by screws 18. In the housing of the handle 17 there is a distribution channel 14 connecting the spool 15 controlled by pivotally mounted on the handle 17 with the lever 11, the sealing sleeve 13 and the spring 16. The spool 15 is moved using the rod 12.

The device operates as follows. Liquid is supplied to the device by a high pressure pump through an inlet hose attached to the nozzle 20. When the washing fluid is supplied through the distribution channel 14, it enters the channel 2 of the housing 1 through the channel A, passing between the housing 1 and the cone 4, is thrown out through the holes in the frame 6 In this case, there will be a “fan-shaped” liquid stream designed to remove loosely bound contaminants from the outer surfaces of the internal combustion engine. To change the operating mode, it is necessary to press the lever 11, while the spool 15 will move to the right, closing the channel A of the handle 17. The liquid passes through the channel 3 through the tube 3 to the cavitation generator 8, where, passing through the nozzle 10, it narrows sharply. With a sharp narrowing to a value corresponding to d _k , a pressure drop occurs to a critical value necessary for the appearance of cavitation bubbles, in which significant energy is concentrated, sufficient to increase the cleaning ability of the jet. As a result, the washing liquid in the cavitation mode through the cavitation generator 8, which is interchangeable depending on the diameter of the holes to be cleaned, is supplied to the contaminated surface. The surfaces are cleaned with a cavitation jet from weakly and medium-related engine contaminants.

To change the operating mode, carbon dioxide is supplied into the body of the body through a supply hose attached to the fitting 21. At the outlet of the tube 9, carbon dioxide expands sharply and cools, forming ice granules upon contact with water. As a result, in the cavitation generator 8 there will be a mixture of ice granules with a cavitation jet. After that, the cavitation-granulated mixture is supplied under pressure to the contaminated surface, as a result of which the internal channels of the internal combustion engine are completely cleaned of all types of pollution with less labor than in the cavitation mode.

Claims (4)

1. A device for cleaning the engine, comprising a housing with a through channel expanding in the front part and a cone located in it, facing a vertex inside the body, a tube mounted coaxially to the through channel, one end attached to the body, and a handle with a lever and a spool pivotally mounted on it, characterized in that it is equipped with an additional tube and a cavitation generator connected with it, having a tapering part, determined by the formula:

where d _to , D ₀ - respectively, the diameters at the critical section of the channel and at the outlet of the injector;
P ₀ , P ₂ - respectively, the pressure at the outlet and at the inlet to the injector;
K _s , K _h - respectively, the total coefficient of hydraulic losses and the coefficient of hydraulic losses for the narrowing channel;
R is the radius of the cavitation particle, which determines the depth of its penetration into the pollution particle. 2. The device according to claim 1, characterized in that the cavitation generator is a replaceable nozzle in the channel of the tube with an injector located inside it and a communicated additional tube for supplying carbon dioxide. 3. The device according to claim 1 or 2, characterized in that the injector is made in the form of a cavity having the shape of an hourglass with a certain narrowing hole. 4. The device according to claim 2, characterized in that the interchangeable nozzles are made with an external thread.

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