JPH03143560A - Detecting structure of centrifugal electrostatic oil cleaning machine - Google Patents

Abstract

PURPOSE:To prevent the shorting of the electrodes in the oil cleaning machine by providing projecting parts for detection which project to an oil tank side on the electrode plates mounted at the center of rotation in the oil tank and detecting the deposition of the contaminants by the electric discharge or energization of the contaminants and the projecting parts for detection. CONSTITUTION:The rotary oil tank 3 which is provided with the electrode on the inner side and houses the contaminated oil and the plural electrode plates 19 mounted at the center of rotation in the oil tank 3 are provided. The electrode 20 on the oil tank side and the electrode plates 19 are varied in polarity. The projecting parts 37 for detection which projects to the oil tank 3 side from the electrode plates 19 are provided on the electrode plate 19 side toward the contaminants 41 accumulated on the oil tank 3 side to detect the deposition of the contaminants 41 by the electric discharge or energization of the contaminants 41 and the projecting parts 37 for detection. As a result, the shorting of the electrodes in the oil cleaning machine is prevented. The discharge of the contaminants of the projecting parts for detection or the energization by contact is a measure of washing the inside of the oil cleaning machine. The effect of maintenance is thus improved.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a detection structure in a centrifugal electrostatic oil purifier, and more specifically, to a detection structure for detecting the accumulated amount of contaminants separated and accumulated within the oil purifier. It's about structure.

<Prior art> A conventional centrifugal electrostatic oil purifier uses centrifugal force due to rotation to separate contaminants toward the outer rotating inner wall of the oil tank, and separates contaminants between the inner wall of the oil tank and an umbrella electrode plate provided on the central axis. A method is used to separate colloidal contaminant particles by applying a voltage.

<Problems to be Solved by the Invention> However, in the above-mentioned conventional centrifugal electrostatic oil purifier, it is not possible to grasp the accumulated amount of separated contaminants during oil purification work, and the work of removing separated contaminants is done solely by the operator. I relied on my intuition and experience.

Therefore, if the exact maintenance period is not known and the amount of accumulated contaminants is too large, the flow of contaminated oil will become poor and oil purification efficiency will deteriorate significantly, making it difficult to maintain a constant oil purification efficiency. Ta.

Furthermore, troubles such as short circuits due to the contaminants approaching and coming into contact with the umbrella electrode plates are likely to occur, and such short circuits may cause damage to the electrodes or other electrical system failures.

<Means for Solving the Problems> The present invention for solving the above-mentioned problems includes a rotary oil tank 3 for storing contaminated oil with an electrode provided inside, and a rotary oil tank 3 installed on the center of rotation in the oil tank 3. In a structure in which a plurality of electrode plates 19 are provided and the oil tank side electrode and the electrode plates are different in polarity,
On the electrode plate 19 side, a detection protrusion 37 that protrudes from the electrode plate 19 toward the oil tank 3 side is provided toward the contaminants 41 accumulated on the oil tank 3 side, so that the detection protrusion 37 and the contaminant 41 It is characterized by detecting the amount of dyed material 41 attached by discharging or energizing.

<Operation> Contaminants from the contaminated oil in the oil tank 3 are centrifugally separated by the rotation of the oil tank 3, and fine contaminants are also removed by the voltage applied between the oil tank side electrode and the electrode plate 19. Since the detection protrusion 37 protrudes outward more than the other electrode plates 19 and is located closer to the contaminants attached to the oil tank 3 than the other electrode plates 19, discharge due to accumulation of contaminants is caused by the protrusion 37. first occurs between Furthermore, even if no discharge occurs, the protrusion 37 is the first to come into contact with the contaminant 41, and the contact causes electricity to flow. Therefore, by electrically detecting the discharge or the like occurring between the protrusion 37 and the contaminants on the oil tank 3 side, it is possible to know the amount of contaminants accumulated.

<Example> An example of the present invention will be described below in detail based on the drawings. FIG. 1 is an overall view showing a purification circuit system for purifying contaminated oil and the inside of a centrifugal electrostatic oil purifier 1. As shown in FIG.

The centrifugal electrostatic oil purifier 1 includes an oil tank 3 rotatably supported within a movable case, and a motor 5 for rotating the oil tank 3. Contaminated oil is sent from the contaminated oil tank 2 to the oil tank 3 by a pump 4, and oil purified in the oil tank 3 is returned to the contaminated oil tank 2.

Through the circulation of these contaminated oils, the contaminated oils are gradually purified.

The structure of the centrifugal electrostatic oil purifier 1 will be explained below.

A pulley 6 is formed below the oil tank 3, and a belt 7 wrapped around the pulley 6 transmits the driving force of the motor 5 to the oil tank 3, causing the oil tank 3 to rotate.

A drain tank 9 is provided below the oil tank 3.

Contaminants separated by the rotation of the oil tank 3 accumulate in a drain tank 9 located below the oil tank 3 due to their own weight. Contaminants accumulated in the drain tank 9 are discharged from the drain cock U together with oil.

A shaft 13 is erected at the rotation center of the oil tank 3.

The shaft 13 has a tubular shape, and the inside thereof serves as an oil supply path 15 for sending contaminated oil into the oil tank 3. A spout 1 is provided at the base end of the shaft 13.
7 is formed, and contaminated oil flows into the oil tank 3 through the spout 17.

A plurality of heavy electrode plates 19 that spread downward are fixed to the shaft 13 at predetermined intervals, and plate-shaped dust collecting electrode plates 20 are fixed vertically inside the oil tank 3 and are arranged circumferentially at predetermined intervals. They are installed in parallel. The heavy electrode plate 19 has holes 21 at arbitrary positions.
are perforated so that contaminated oil can easily enter between the heavy electrode plates 190.

An oil drain passage 23 is provided above the oil tank 3 and between the oil tank 3 and the shaft 13, and purified oil is sent out to the outside of the oil tank 3.

An insulator 25 is provided between the lower end of the shaft 13 and the bottom of the oil tank 3, and a drain path 24 is formed between the insulator 25 and the oil tank 3. The contaminants separated in the oil tank 3 pass through the drain passage 24 and settle into the drain tank 9. Drain tank 9
A base end insulator 29 is provided on the bottom surface of the base end insulator 29 , and a conductive rod 27 is inserted between the base end insulator 29 and the insulator 25 .

The electrode 31 is connected to the lower end of the conductive rod 27, and the upper end is connected to the shaft I3, and a voltage is applied to the heavy electrode plate 19 attached to the shaft 13 by the conductive rod 27. Note that the distance e between the upper end of the base end insulator 29 and the bottom surface of the drain tank 9 is formed to be sufficiently long. This prevents discharge from occurring between the conductive rod 27 and the drain tank 9 due to the accumulation of contaminants.

FIG. 2 is an enlarged sectional view of the vicinity of the jet nozzle 17. The heavy electrode plate 33 at the lowest position of the heavy electrode plate 19 is not provided with a hole 21, and the contaminated oil supplied through the spout 17 is always guided to the vicinity of the bottom of the oil tank 3. . A detection body 35 is attached between the heavy electrode plate 33 and the insulator 25. As shown in FIG. 3, the detection body 35 has plate-shaped wings extending from the center ring-shaped part in the opposite direction to the heavy electrode plate 3.
3, and the tips of the wings form protrusions 37 that protrude outward from the lower end of the heavy electrode plate 33.

On the other hand, a contaminant 41 is formed in the oil tank 3 at a position opposite to the protrusion 37 to accommodate centrifuged contaminants. When the contaminants 41 accumulate in the storage section 39, the contaminants 4
I gradually approaches the protrusion 37, and the oil tank 3 and the heavy electrode plate 19
The voltage applied between the contaminant 41 and the protrusion 37
A discharge occurs between. The discharge, the protrusion 37 and the contaminants 4
The detection body 35 is energized by contact with 1.

FIG. 4 is a circuit diagram for applying a voltage between the dust collecting electrode plate 20 and the heavy electrode plate 19 of the oil tank 3. AC200 with transformer 51 [
The input voltage of V] is transformed to a high voltage, the transformed current is rectified by a rectifier 53, and a DC voltage is applied between the oil tank 3 and the heavy electrode plate 19. In the structure of this embodiment, a negative electrode is connected to the heavy electrode plate 19 side, and a positive electrode is connected to the dust collection electrode plate 20 side.

In this way, a relay-equipped ammeter 55 is installed in the rectified circuit.
The circuit is set so that when the current reaches a certain value or more, the circuit is opened by a relay. The amount of contaminants 41 is notified by opening the circuit and lighting up a buzzer or lamp attached to the device.

The material of the detection body 35 is a material with good heat resistance that can withstand the heat caused by discharge.

Furthermore, if a plurality of detection bodies 35 are prepared and the amount of protrusion of the protrusion 37 protruded from the other heavy electrode plates 19 is adjusted, the contaminant 4
It becomes possible to freely adjust the timing of the removal work in step 1.

FIG. 5 is an enlarged partial cross-sectional view showing the oil drain path 23 portion of the oil tank 3. FIG. A lid 59 is placed over the top of the oil tank 3, and an insulator 61 is inserted between the shaft 13 and the lid 59, forming an oil drain passage 23 through which drained oil passes. The center of the insulator 61 is the axis 1
A connecting portion 61a is formed to connect to the shaft 13, and an inner insulator 63 is further fitted to the lower end of the connecting portion 61a within the shaft 13. An introduction pipe 57 is provided at the upper part of the connection part 61a.
The upper end of the inner insulator 63 is connected to the lower end of the introduction pipe 57.

By adopting such an insulating structure, it is possible to provide a sufficient distance between the inner wall of the shaft 13 and the introduction tube 57, so that discharge caused by contaminants accumulated inside the shaft 13 can be prevented.

The shape of the insulator 61 is such that the lower edge of the umbrella-shaped outer periphery formed along the lid 59 and the lower end of the connecting portion 61a are at the same height. Therefore, materials can be saved during manufacturing, and by attaching the inner insulator 63 separately, the insulation distance can be made sufficiently long.

<Effects of the Invention> According to the detection structure of the present invention configured as described above, since the detection contact portion is provided to protrude from the electrode plate of the pond, the electrode plate does not discharge the contaminants accumulated on the oil tank side. Alternatively, the detection protrusion is discharged or energized before energization to notify the amount of contaminants, so there is an advantage that damage to the electrodes in the oil purifier can be prevented.

In addition, energization due to discharge or contact with contaminants in the detection protrusion serves as a guide for cleaning the inside of the oil purifier, improving maintenance efficiency. As a result, the cleaning efficiency of the oil purifier can be easily maintained constant at all times.

[Brief explanation of the drawing]

Figure 1 is an overall view showing the purification circuit system for purifying contaminated oil and the inside of the centrifugal electrostatic oil purifier, Figure 2 is an enlarged sectional view of the vicinity of the oil tank spout, Figure 3 is a plan view of the sensing body, and Figure 3 is a top view of the sensing body. FIG. 4 is a voltage transformation circuit diagram of the voltage applied to the electrodes, and FIG. 5 is an enlarged partial cross-sectional view showing the oil drain passage of the oil tank. 1: Centrifugal electrostatic oil purifier 3: Oil tank 19: Heavy electrode plate 37: Protrusion 41: Contaminants

Claims (1)

[Claims] 1) Rotating oil tank (3) containing contaminated oil with electrodes installed inside.
) and a plurality of electrode plates (19) attached on the rotation center in the oil tank (3), and in a structure in which the oil tank side electrode and the electrode plate are different poles, the electrode plate (19) side is a detection protrusion (
37) is provided facing the contaminant (41) accumulated on the oil tank (3) side, and the contaminant (41) and the detection protrusion (37)
A detection structure in a centrifugal electrostatic oil purifier that detects the amount of contaminants (41) attached by discharging or energizing with.