JP2003175437A - Eddy current circulation type coolant purifying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an eddy current circulation type coolant purifying apparatus capable of improving purifying efficiency during purifying coolant by eddy current. <P>SOLUTION: This apparatus comprises a first coolant tank 1 which has a roughly circular cross section, accommodates spent coolant guided from a processing device K in an eddy current condition and has a discharge port 1a discharging the coolant from its center bottom surface, a roughly cylindrical second coolant tank 2 which is formed out of a roughly cylindrical shape surrounding the side and lower parts of the first coolant tank 1 and accommodates the coolant at the outside of the first coolant tank 1 in an eddy current condition and is communicated with the discharge port 1a of the first coolant tank 1 at a lower part, flow passages L1, L7 and L5 which guide the coolant discharged from the discharge port 1a and introduce the coolant to the second coolant tank 2, and a circulating passage L2 which discharges the coolant with high cleanliness adjacent to the inner wall of the second coolant tank 2 to the processing device K. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a swirl circulation type coolant purifying device for purifying a coolant discharged from a processing device and mixed with sludge and the like by a vortex flow, and sending the coolant again to the processing device to circulate and use the coolant. Regarding

[0002]

2. Description of the Related Art The coolant discharged from a processing device such as a grinding processing device is mixed with sludge and the like that has flowed out from a processing base material during processing, and the used coolant is sent again to the processing device for reuse. In order to do so, it needs to be purified. A circulation-type coolant purification device that performs such purification and circulation is disclosed in, for example, Japanese Patent Laid-Open No. 2001-277067.

The conventional circulating-type coolant purifying apparatus disclosed in the above publication has a cylindrical coolant tank for accommodating used coolant, and mixes by generating a vortex in the tank. It is a vortex circulation type that collects sludge, etc. on the central bottom surface of the same tank and removes it. More specifically, the coolant containing sludge accumulated on the bottom surface of the center of the tank is pulled up by the pump to above the tank, and the sludge is adsorbed and removed by the magnet of the magnet sorter, while cleaning the vicinity of the inner wall surface of the tank. It was configured to send high-quality coolant again to the processing equipment with a separate pump.

[0004]

However, in the conventional swirl circulation type coolant purifying apparatus described above, since there is only one tank (tank) for storing the used coolant,
There is a possibility that the coolant with high cleanliness near the inner wall of the tank and the coolant with low cleanliness near the center bottom surface of the tank may be mixed, and the purification efficiency may be deteriorated.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a swirl circulation type coolant purifying apparatus capable of improving the purifying efficiency at the time of purifying the coolant by the swirl flow.

[0006]

The invention according to claim 1 is
In a vortex circulation type coolant purification device for circulating and utilizing the coolant discharged from the processing device and mixed with sludge and the like by a vortex flow, and recirculating the coolant to the processing device, the cross section is substantially circular, The coolant introduced from the processing device is accommodated in a vortex flow state, and includes a first coolant tank having a discharge port for discharging from a central bottom surface, and a substantially cylindrical shape surrounding at least a side and a lower side of the first coolant tank. While storing the coolant in a vortex state outside the first coolant tank,
A substantially cylindrical second coolant tank communicating with the discharge port of the first coolant tank below and a coolant discharged from the discharge port are introduced, and the coolant is discharged to the second coolant tank.
It is characterized by comprising a flow passage introduced into the coolant tank, and a circulation passage for feeding the coolant having a high cleanliness in the vicinity of the inner wall of the second coolant tank to the processing device.

According to this structure, the used coolant mixed with sludge or the like is accommodated in the first coolant tank while generating a swirl flow, is discharged from the discharge port on the central bottom surface, reaches the flow passage, and reaches the flow passage. The coolant is reintroduced into the second coolant tank, and the one with a low degree of cleanliness is discharged from the discharge port by the vortex flow, while the one with a high degree of cleanliness is discharged to the circulation path and fed again to the processing equipment for recycling. It

Since a vortex is generated also in the second coolant tank, the coolant with low cleanliness is selected on the center bottom surface, and the coolant with high cleanliness is selected near the inner wall, and the coolant near the inner wall is processed through the circulation path. While being sent to the apparatus, the coolant on the center bottom surface is discharged from the discharge port and guided to the first coolant tank through the flow passage.

The invention according to claim 2 is characterized in that the first coolant tank has a shape in which the inner diameter is reduced from the upper end to the lower end thereof.

According to a third aspect of the present invention, the introduction port for introducing the coolant into the first coolant tank or the second coolant tank is arranged so as to be oriented in a tangential direction in the first coolant tank or the second coolant tank. The feature is that the introduced coolant is configured to generate a swirl flow.

According to a fourth aspect of the present invention, the coolant flowing through the flow passage is introduced while generating a swirl flow, and the coolant having a high cleanliness level is guided to the second coolant tank while the cleanliness level discharged from the lower side is introduced. Is equipped with a tornado type purifying device for introducing a low coolant to the first coolant tank.

According to a fifth aspect of the present invention, a coolant having a low cleanliness discharged from the lower side of the tornado type purifying device is accommodated, oil is suspended in the upper position and sludge is deposited in the lower position, and at the intermediate position. It is characterized by comprising a separation tank for guiding the coolant to the first coolant tank.

According to a sixth aspect of the present invention, the coolant discharged from the processing device is accommodated, the iron component in the coolant is removed by a magnet, and the coolant from which the iron component is removed is introduced into the first coolant tank. It is characterized in that it is equipped with a magnet type sorting device.

According to a seventh aspect of the present invention, the flow passage is branched between the discharge port of the first coolant tank and the tornado type purifying device, and the tip of the branched flow passage is used as the magnet type sorting device. It is characterized by being arranged.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be specifically described below with reference to the drawings. The swirl circulation-type coolant purifying apparatus according to the present embodiment purifies the coolant mixed with sludge and the like discharged from the processing apparatus (grinding processing apparatus) and flowing out from the metal processing base material by a swirl flow, and sends the coolant again to the processing apparatus. The first coolant tank 1, the second coolant tank 2, the tornado type purification device 4, the separation tank 5, and the flow passage L1 are used to circulate and use the coolant according to FIG. , And a circulation path L2.

The first coolant tank 1 has a discharge port 1a for introducing the coolant introduced from the processing device K through the magnet type sorting device 3 and storing it in a vortex state and discharging it from the central bottom surface. As shown in FIGS. 2 to 4, the tank has a substantially circular (funnel-shaped) cross section whose inner diameter is reduced from the upper end to the lower end. The first coolant tank 1 may have a cylindrical shape, but by making the first coolant tank a funnel shape, a swirl can be efficiently generated and the first coolant tank 1 has a cylindrical shape. Compared with the case, the coolant on the bottom surface of the center of the second coolant tank 2 can be made to flow smoothly to the discharge port 1a of the first coolant tank 1.

Further, by generating a vortex flow in the first coolant tank 1, mixed sludge and the like can be efficiently accumulated on the central bottom surface, and the coolant containing a large amount of such sludge can be smoothly discharged from the discharge port 1a. It can be done.

In FIG. 1, a flow path L for guiding the used coolant from the processing device K to the magnet type sorting device 3 is indicated by L.
3, L4 is a flow path that guides the coolant from which iron has been removed by the magnet type sorting device 3 to the first coolant tank 1. The flow channel (including other flow channels) is mainly made of a flexible tube, but may be a flow channel formed of another material.

Further, as shown in FIG. 2, the coolant inlet a at the tip of the flow path L4 is provided in the first coolant tank 1
Is arranged so as to be tangential to the coolant, and the coolant to be introduced is configured to easily generate a swirl flow. As a result, when the coolant is introduced into the first coolant tank 1, a vortex flow is naturally generated, so that a separate drive pump or the like is unnecessary, and the manufacturing cost and running cost can be reduced.

Further, the coolant inlet port b at the tip of the flow path L6 extending from the separation tank 5 is also arranged so as to be tangential to the first coolant tank 1 and flows from the inlet port a. In addition to this, the vortex flow is further easily generated. The directions of the inlets a and b may be variable so as to generate a desired vortex flow.

The magnet type sorting device 3 stores the coolant discharged from the processing device K and removes iron in the coolant with a magnet. As shown in FIG. 5, a tank 3a for storing the coolant is provided. A roller type magnet M rotatable by the drive roller R, a scraper 3c for scraping off the iron adsorbed on the roller type magnet M, and the scraper 3
It is mainly composed of a storage box 3d for storing the iron component scraped by c and a partition plate 3b arranged in the tank 3a for guiding the coolant to the roller type magnet M.

As a result, the iron component contained in the coolant introduced from the flow path L3 (or the flow path L8) is transferred to the roller magnet M.
Since it is possible to adsorb and remove the iron content and to introduce the iron content-removed material into the first coolant tank 1 through the flow path L4, the cleanliness of the coolant introduced into the first coolant tank 1 can be improved. It can be raised to some extent, and a series of subsequent purifying actions can be smoothly performed.

The second coolant tank 2 has a cylindrical shape surrounding the sides and the lower side of the first coolant tank 1 (there is no need to have the lower side), and the coolant is accommodated in a vortex state outside the first coolant tank 1. In addition, the central bottom surface (downward) communicates with the discharge port 1a of the first coolant tank. That is, since the introduction port c of the coolant flow path L5 extended from the tornado type purification device 4 is arranged in the tangential direction in the second coolant tank,
In the second coolant tank 2, a swirl flow similar to that in the first coolant tank 1 can be generated.

Due to the vortex flow in the second coolant tank 2 as described above, mixed sludge and the like can be accumulated on the central bottom surface, and only the coolant containing a large amount of sludge is discharged from the discharge port 1.
It is configured so that it can be discharged from a. That is, the coolant with low cleanliness accumulated in both the first coolant tank 1 and the second coolant tank 2 is discharged from the discharge port 1a.

The flow passages (L1, L7 and L5) are passages for guiding the coolant discharged from the discharge port 1a and for introducing the coolant into the second coolant tank 2 via the tornado type purification device 4. is there. For convenience, the flow path from the outlet 1a to the branch point W of the flow path L7 and the flow path L8 is defined by the flow path L1 and the branch point W through the tornado purification device 4.
Is defined as the flow passage L7, and the flow passage from the tornado type purification device 4 to the second coolant tank 2 is defined as L5.

The coolant in the flow passage L1 is pumped by the pump P1.
Are partially sucked up to the tornado type purifying device 4 through the flow passage L7 and the other to the magnet type sorting device 3 through the flow path L8. That is, the flow passage is branched between the discharge port 1a and the tornado type purification device 4, and the tip of the branched flow path L8 is arranged in the magnet type sorting device 3. With such a configuration, a part of the coolant with low cleanliness discharged from the discharge port 1a can be sent to the magnet type sorting device 3 again to further remove iron, and reliable purification can be performed. The flow path L8 is provided with a valve V1 so that the flow path L8 can be freely flown or blocked.

The circulation path L2 is composed of a passage extending from the opening 2a formed in a part of the wall surface of the second coolant tank 2 to the processing device K through the pump 2 and near the inner wall of the second coolant tank 2. Highly clean coolant in processing equipment K
Is configured to be sent to. Here, the opening 2a is
Since it is formed on the wall surface of a predetermined height from the bottom surface of the second coolant tank 2, of the coolant accommodated in the second coolant tank 2, oil floating on the upper surface side, iron content (sludge) deposited on the bottom surface, etc. It is possible to send only the coolant with extremely high cleanliness to the processing device K while avoiding foreign matter.
The circulation path L2 is provided with a valve V2, which is configured to be opened during processing by the processing machine K and closed during non-processing.

The tornado type purifying device 4 introduces the coolant flowing through the flow passage L7 while generating a vortex flow, and guides the coolant having high cleanliness above to the second coolant tank 2 through the flow passage L5, while lowering the coolant. The coolant having a low cleanliness discharged from is introduced into the first coolant tank 1 through the separation tank 5 and the flow path L6. As shown in FIG. 6, the tornado type purifying device 4 is composed of a substantially cylindrical member having a reduced diameter portion in the lower part thereof, and an accommodating space 4a for accommodating the coolant guided from the flow passage L7 while generating a vortex is provided inside. And a discharge port 4b communicating with the accommodation space 4a is formed below.

Since the connection port (coolant introduction port) of the flow passage L7 is directed tangentially to the accommodation space 4a (offset with respect to the central axis),
The introduced coolant is designed to naturally generate a swirl. Due to this vortex flow, the coolant having low cleanliness including sludge and the like is discharged from the lower discharge port 4b, and the coolant having high cleanliness flows from the connection port (coolant outlet port) with the upper flow channel L5 to the flow channel L5. After that, it is guided to the second coolant tank 2.

The separation tank 5 accommodates the coolant with low cleanliness discharged from the discharge port 4b of the tornado type purification device,
The oil is suspended in the upper position while the sludge is precipitated in the lower position, and the coolant in the intermediate position is guided to the second coolant tank. As shown in FIG. 7, this separation tank is composed of a tank 5a capable of accommodating a coolant, and the inside of the separation tank 5 is separated by a partition plate 5b into storage spaces S1 and S2, while a partition plate 5b is provided. An opening 5ba is formed in a part of the above, so that only the coolant in the vicinity of the middle in the height direction of the coolant introduced into the accommodation space S1 can flow into the accommodation space S2.

Therefore, only the coolant having a high degree of cleanliness other than the oil content floating in the accommodation space S1 and the precipitated iron content (sludge) reaches the accommodation space S2, and the purification can be performed more reliably. The partition plate 5b in the tank 5a
The wall surface opposed to is an inclined surface 5aa as shown in the figure, which makes it easy to scrape off iron components such as sludge deposited on the bottom surface by the scraping tool T or the like.

Next, the coolant purifying operation with the above configuration will be described. The used coolant used in the processing device K passes through the flow path L3 and the magnet type sorting device 3
To the first coolant tank 1 through the flow path L4. Since the swirl flow is generated in the first coolant tank 1, the coolant with low cleanliness including sludge and the like is efficiently discharged from the discharge port 1a on the central bottom surface. Also, the first
Due to the vortex flow of the coolant tank 1, the coolant in the first coolant tank 1 can be efficiently discharged from the discharge port 1a, and the coolant with low cleanliness in the second coolant tank 2 can be drawn into the discharge port 1a.

The coolant discharged from the discharge port 1a is
It is sucked up by the pump P1 via the flow passage L1, and is branched into the flow passage L7 and the flow passage L8. The coolant flowing through the flow path L8 returns to the magnet type sorting apparatus 3, and iron components are removed again by the roller magnet M to reach the first coolant tank 1. On the other hand, the coolant flowing through the flow passage L7 reaches the tornado-type purification device 4, and the one having a low degree of cleanliness is discharged from the discharge port 4b by the action of the internal vortex and is stored in the storage space S1 of the separation tank 5 and is cleaned. The highly-cooled one reaches the second coolant tank 2 through the flow passage L5.

Further, the coolant introduced into the second coolant tank 2 has a low cleanliness of coolant including sludge and the like accumulated on the central bottom surface by a vortex flow, and is discharged from the discharge port 1a like the first coolant tank 1. While the same purifying action is performed, only the coolant with high cleanliness in the vicinity of the inner wall flows out from the opening 2a to the circulation path L2 and is sent to the processing device K by the pump P2. As a result, the coolant discharged from the processing device K can be purified and sent to the processing device K again, and the coolant can be circulated.

As described above, the coolant having high cleanliness is separated into the second coolant tank 2 and the coolant having low cleanliness is separated into the first coolant tank 1 for purification, so that those having high cleanliness and those having low cleanliness are purified. Occasionally mixing can be avoided and the purification efficiency can be improved.

Although the present embodiment has been described above, the present invention is not limited to this. For example, instead of the purifying means such as the magnet type sorting device 3, the tornado type purifying device 4, the separation tank 5, etc. Can be used as a general-purpose purifying means, and these combinations can be used in various ways. That is, any one of the magnet type sorting device 3, the tornado type purification device 4 and the separation tank 5 can be omitted or placed at another position.

Further, in the present embodiment, although it is applied to purify the coolant used in the grinding processing device, the coolant used in another processing device (such as a cutting device) which produces sludge during processing is used. It may be configured to purify. Further, in the present embodiment, in order to ensure the purification, the flow passage 1 is branched and divided into the flow passage L8 and the flow passage L7, but only the flow passage L7 is not branched (that is, the flow passage L7). L8 may be abolished).

[0038]

According to the first aspect of the present invention, since the coolant with low cleanliness is stored in the first coolant tank and the coolant with high cleanliness is stored in the second coolant tank, when cleaning by vortex flow In the above, it is possible to avoid the mixture of high cleanliness and low cleanliness, and improve the purification efficiency.

According to the second aspect of the invention, since the diameter of the first coolant tank is reduced downward, a swirl can be efficiently generated, and the coolant on the bottom surface of the center of the second coolant tank is 1 It can be made to flow smoothly to the discharge port of the coolant tank.

According to the third aspect of the invention, since a vortex can be generated by utilizing the flow of the coolant introduced into the first coolant tank or the second coolant tank, a separate drive source is provided. Manufacturing cost and running cost can be suppressed as compared with the above.

According to the fourth aspect of the present invention, the coolant that has reached the flow passage is purified by the tornado type purification device, and the one with high cleanliness is introduced to the second coolant tank, and the one with low cleanliness is first. Since it is led to the coolant tank, it is possible to perform reliable purification.

According to the fifth aspect of the present invention, the coolant with low cleanliness discharged from the tornado type purifying device is separated in the separation tank, and the coolant in which the oil and sludge are separated is guided to the first coolant tank. Therefore, more reliable purification can be performed.

According to the sixth aspect of the invention, since the coolant discharged from the processing device and containing a large amount of sludge is introduced into the first coolant tank, the iron content is removed by the magnet type sorting device. It is possible to smoothly carry out the purification action by the vortex flow of, and it is possible to perform more reliable purification.

According to the seventh aspect of the present invention, the coolant discharged from the discharge port is branched, and one of them is guided to a tornado type purifying device or a separating device, and the other is guided to a magnet type sorting device to be further magnetized. Since iron is removed, more reliable purification can be performed.

[Brief description of drawings]

FIG. 1 is an overall schematic diagram showing a vortex circulation type coolant purifying apparatus according to an embodiment of the present invention.

FIG. 2 is a top view showing a first coolant tank and a second coolant tank in the vortex circulation type coolant purifying apparatus according to the embodiment of the present invention.

3 is a schematic sectional view taken along line III-III in FIG.

4 is a schematic sectional view taken along line IV-IV in FIG.

FIG. 5 is a schematic sectional view showing a magnet type sorting device in the vortex circulation type coolant purifying device according to the embodiment of the present invention.

6A and 6B are a top view and a partially broken front view showing a tornado type purification device in the vortex circulation type coolant purification device according to the embodiment of the present invention.

FIG. 7 is a schematic cross-sectional view showing a separation tank in the vortex circulation type coolant purifying apparatus according to the embodiment of the present invention.

[Explanation of symbols] 1 ... 1st coolant tank 2 ... Second coolant tank 3 ... Magnet type sorting device 4 ... Tornado type purifier 5 ... Separation tank L1, L5, L7 ... Flow path L2 ... Circulation L2-L4, L6, L8 ... Channel K ... Processing device (grinding device) V1, V2 ... Valve P1, P2 ... Pump

─────────────────────────────────────────────────── ─── Continued Front Page (51) Int.Cl. ⁷ Identification Code FI Theme Coat (Reference) B04C 9/00 B04C 9/00 B24B 55/03 B24B 55/03

Claims (7)

[Claims] 1. A vortex circulation type coolant purifying apparatus for circulating and recycling the coolant discharged from a processing apparatus and mixed with sludge and the like by a vortex flow and sending the coolant again to the processing apparatus. A first coolant tank having a shape, which stores the coolant guided from the processing device in a vortex state and has a discharge port for discharging the coolant from a central bottom surface; and a substantially cylindrical shape surrounding at least a side and a lower side of the first coolant tank. The second coolant tank, which has a shape and accommodates the coolant in a vortex state outside the first coolant tank, communicates with the discharge port of the first coolant tank below, and guides the coolant discharged from the discharge port. With
A swirl circulation type, comprising: a flow passage for introducing the coolant into the second coolant tank; and a circulation passage for feeding the coolant having high cleanliness in the vicinity of the inner wall of the second coolant tank to the processing device. Coolant purification device. 2. The swirl circulation-type coolant purifying apparatus according to claim 1, wherein the first coolant tank has a shape in which the inner diameter is reduced from the upper end to the lower end. 3. An inlet for introducing the coolant into the first coolant tank or the second coolant tank is arranged so as to be tangential to the first coolant tank or the second coolant tank, and the coolant to be introduced causes a vortex flow. The swirl circulation-type coolant purifying apparatus according to claim 1 or 2, which is configured to generate. 4. The coolant flowing through the flow passage is introduced while generating a swirl flow, and the coolant with high cleanliness above is guided to the second coolant tank, while the coolant with low cleanliness discharged from below is passed through the second coolant tank. The swirl circulation-type coolant purification device according to any one of claims 1 to 3, further comprising a tornado-type purification device that leads to one coolant tank. 5. A low-cleanliness coolant discharged from the lower side of the tornado-type purification device is accommodated, oil is suspended at an upper position and sludge is settled at a lower position, and a coolant at an intermediate position is used as the first coolant. The vortex circulation type coolant purifying apparatus according to claim 4, further comprising a separation tank for leading to the tank. 6. A magnet type sorting device for accommodating the coolant discharged from the processing device, removing iron in the coolant with a magnet, and introducing the coolant from which iron has been removed into the first coolant tank. The swirl circulation-type coolant purifying apparatus according to any one of claims 1 to 5, characterized by being provided. 7. The flow passage is branched between the discharge port of the first coolant tank and the tornado type purification device,
The swirl circulation type coolant purifying apparatus according to claim 6, wherein a tip of the branched flow path is arranged in the magnet type sorting apparatus.