JPWO2018168683A1 - Coolant and cooling equipment - Google Patents

Abstract

Provided is a cooling material and a cooling device capable of reducing an adverse effect on a human body. A cooling device 1A for cooling a prime mover mounted on a vehicle, comprising, in order to cool a prime mover 2, a polyol ester which is a lubricating oil having a freezing point of -70 ° C or less without containing ethylene glycol as a main component. And a coolant passage 3 for circulating the coolant and a pump 4 for flowing the coolant in the coolant passage 3. The pump 4 is cooled by a gear. It is a gear pump for flowing the material.

Description

  The present invention relates to a coolant and a cooling device.

  2. Description of the Related Art Conventionally, an antifreeze containing ethylene glycol as a main component has been used as a coolant for cooling a prime mover (for example, an engine) mounted on a vehicle (for example, see Patent Document 1). The performance required as a coolant is to have a freezing point of −30 ° C. or less. An antifreeze containing ethylene glycol as a main component has this performance.

JP-A-11-179756

  However, a conventional coolant, that is, an antifreeze containing ethylene glycol as a main component is highly toxic and may adversely affect the human body.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a cooling material and a cooling device capable of reducing an adverse effect on a human body.

In order to solve the above problems, the coolant according to the present invention is:
A coolant for cooling a prime mover mounted on a vehicle,
Without containing ethylene glycol,
It is characterized by containing a polyol ester which is a lubricating oil having a freezing point of −70 ° C. or less as a main component.

In the above coolant,
In the polyol ester, a magnetic functional material is dispersed,
The magnetic functional material preferably has an average particle size of 10 μm or less, and has a temperature-sensitive characteristic in which the magnetization decreases as the temperature increases in a normal temperature range.

In order to solve the above-described problems, a cooling device according to an embodiment of the present invention includes:
A cooling device for cooling a prime mover mounted on a vehicle,
A coolant containing a polyol ester having a freezing point of -70 ° C or lower without containing ethylene glycol,
A coolant passage for circulating the coolant,
A pump for flowing the coolant in the coolant channel,
With
The pump is a gear pump that causes the coolant to flow by a gear.

In order to solve the above-described problems, a cooling device according to another embodiment of the present invention includes:
A cooling device for cooling a prime mover mounted on a vehicle,
Without ethylene glycol, contains polyol ester whose lubricating oil has a freezing point of -70 ° C or less, has an average particle size of 10 µm or less, and has a temperature-sensitive property that magnetization decreases with increasing temperature in a normal temperature range. A coolant in which the magnetic functional material is dispersed,
A coolant passage for circulating the coolant,
A cooling unit that is provided in the coolant channel and cools the coolant,
A magnetic field generating unit configured to generate a magnetic field in a first region inside the cooling unit and a second region outside the cooling unit adjacent to the first region.

The cooling device,
Further comprising a pump for flowing the coolant in the coolant channel,
The pump can be configured to be a gear pump that causes the coolant to flow through gears.

The cooling device,
It can be configured not to include a pump for flowing the coolant in the coolant channel.

In the cooling device,
The motor comprises the motor and an inverter that drives the motor,
The cooling unit is provided adjacent to the inverter,
The magnetic field generation unit may be configured to generate a magnetic field in the inverter that is the second region.

  Advantageous Effects of Invention According to the present invention, it is possible to provide a coolant and a cooling device that can reduce adverse effects on a human body.

It is a figure showing the cooling device for engines concerning a 1st embodiment. It is a figure showing the cooling device for motors concerning a 1st embodiment. (A) is a figure for explaining the magnetic drive effect in a flow path. (B) is a distribution diagram of the magnetic field and the magnetization in the flow path of (A). It is a figure showing the cooling device for engines concerning a 2nd embodiment. It is a figure showing the cooling device for motors concerning a 2nd embodiment.

  Hereinafter, embodiments of a coolant and a cooling device according to the present invention will be described with reference to the accompanying drawings.

[First Embodiment]
(Coolant)
The coolant according to the present embodiment is for cooling a prime mover (for example, an engine or a motor) mounted on a vehicle such as an automobile. The coolant according to the present embodiment is an antifreeze liquid containing, as a main component, polyol ester (POE) which is a lubricating oil having a freezing point of −70 ° C. or less without containing ethylene glycol. As such a polyol ester, for example, neopentyl glycol diester can be used.

  As described above, the polyol ester of the present embodiment has a freezing point of −70 ° C. or less, and thus satisfies the performance required for a coolant (having a freezing point of −30 ° C. or less). Further, the polyol ester can have a viscosity similar to that of ethylene glycol. However, unlike ethylene glycol, it has low toxicity and has little risk of adversely affecting the human body. Furthermore, polyol esters are superior to ethylene glycol in lubricity, heat resistance, low-temperature fluidity, flame retardancy, and biodegradability.

  Therefore, according to the coolant according to the present embodiment, since it does not contain ethylene glycol, adverse effects on the human body can be reduced. In addition, since the coolant according to the present embodiment contains a polyol ester as a main component, it is possible to achieve energy saving and a long life as a coolant.

(Engine cooling system)
Next, as a cooling device according to the present embodiment, an engine cooling device for cooling an engine mounted on a vehicle such as an automobile will be described.

  FIG. 1 shows an engine cooling device 1A according to the present embodiment. The engine cooling device 1 </ b> A uses the coolant according to the present embodiment to cool the engine 2. The engine cooling device 1A includes an annular coolant passage 3 for circulating coolant, a pump 4 for flowing coolant in the coolant passage 3, and a radiator 5 for cooling the coolant (the present invention). A cooling unit) and a valve 6 for switching a flow path according to the temperature of the coolant.

  The pump 4, the valve 6, and most of the coolant passage 3 (the right side of the valve 6) are provided in the engine 2. The radiator 5 and a part of the coolant flow path 3 (a part connecting the valve 6 and the radiator 5) are provided outside the engine 2.

  The valve 6 has a temperature detecting means for detecting the temperature of the coolant. When the temperature of the coolant is higher than a predetermined temperature, the valve 6 switches the path so that the coolant passes through the inside and outside of the engine 2, while the temperature of the coolant changes to a predetermined temperature. If lower, the path is switched so that the coolant circulates only in the engine 2.

  The pump 4 is a gear pump that causes the coolant to flow by gears. When the coolant is an antifreeze containing ethylene glycol as a main component, a turbo pump is generally used because ethylene glycol cannot flow with a gear pump due to low lubricity of ethylene glycol. On the other hand, the engine cooling device 1A according to the present embodiment uses an antifreeze liquid containing a polyol ester as a main component without containing ethylene glycol, so that a gear pump can be used as the pump 4.

  Since the gear pump is smaller than the turbo pump, according to the engine cooling device 1A according to the present embodiment, the overall size of the device can be reduced as compared with a conventional engine cooling device using a coolant made of ethylene glycol. Will be possible.

(Motor cooling device)
Next, as a cooling device according to the present embodiment, a motor cooling device for cooling a motor mounted on a vehicle such as an electric vehicle and an inverter for driving the motor will be described.

  FIG. 2 shows a motor cooling device 11A according to the present embodiment. The motor cooling device 11A uses the coolant according to the present embodiment to cool the motor 12a and the inverter 12b. The motor cooling device 11A includes an annular coolant flow path 13 for circulating the coolant, a pump 14 for flowing the coolant in the coolant flow path 13, and a radiator 15 for cooling the coolant (the present invention). “Equivalent to a“ cooling unit ”).

  The motor cooling device 11A uses a gear pump as the pump 14, similarly to the engine cooling device 1A described above. Therefore, according to the motor cooling device 11A according to the present embodiment, it is possible to reduce the size of the entire device as compared with a conventional engine cooling device using a coolant made of ethylene glycol.

[Second embodiment]
(Coolant)
The coolant according to the present embodiment is for cooling a prime mover (for example, an engine or a motor) mounted on a vehicle such as an automobile. The coolant according to the present embodiment is an antifreeze liquid containing no ethylene glycol and mainly containing a polyol ester having a freezing point of −70 ° C. or less as a lubricating oil (for example, containing 60% by volume or more). This is common to the first embodiment.

  Therefore, according to the coolant according to the present embodiment, since it does not contain ethylene glycol, adverse effects on the human body can be reduced. In addition, since the coolant according to the present embodiment contains a polyol ester as a main component, it is possible to achieve energy saving and a long life as a coolant.

  On the other hand, the coolant according to the present embodiment differs from the first embodiment in that the magnetic functional material is dispersed in the polyol ester. The magnetic functional material of the present embodiment has magnetic particles (for example, magnetic particles having an average particle size of 10 μm or less and having temperature-sensitive characteristics in which magnetization decreases with an increase in temperature in a normal temperature range (for example, 5 ° C. to 35 ° C.) , Manganese zinc ferrite). The magnetic functional material may be a magnetic fluid in which the magnetic particles are dispersed in a mother liquor (for example, water).

  The magnetic functional material behaves as a substance having magnetization when a magnetic field is applied. For example, as shown in FIG. 3, when a left-right symmetric magnetic field H is applied using a magnet, the magnetic functional material has a magnetization M corresponding to the magnetic field H. Here, when a region on one side of the magnetic field H (the region on the left side in FIG. 3) is cooled by the cooling unit, the magnetization M of the magnetic functional material becomes: The area on one side of the cooled magnetic field H is larger than the area on the other side (the area on the right side in FIG. 3). As a result, the magnetic body force F1 in one region becomes larger than the magnetic body force F2 in the other region, and a driving force (magnetic driving effect) from the left side to the right side in FIG. 3 is generated.

  Therefore, since the coolant according to the present embodiment includes the magnetic functional material having the temperature-sensitive characteristics, the fluidity of the coolant can be improved by using the magnetic driving effect.

(Engine cooling system)
Next, as a cooling device according to the present embodiment, an engine cooling device for cooling an engine mounted on a vehicle such as an automobile will be described.

  FIG. 4 shows an engine cooling device 1B according to the present embodiment. The engine cooling device 1B uses the coolant according to the second embodiment. The engine cooling device 1B is obtained by adding a magnet 7 (corresponding to a “magnetic field generating unit” of the present invention) to the engine cooling device 1A according to the first embodiment.

  As the magnet 7, for example, as shown in FIG. 3, a pair of permanent magnets arranged in parallel with different poles can be used. The magnet 7 is provided to generate a magnetic field in a first area inside the radiator 5 and a second area outside the radiator 5 adjacent to the first area.

  Specifically, the magnet 7 includes a radiator 5, a coolant passage 3 connecting the radiator 5 and the pump 4 (in FIG. 4, a coolant passage 3 connecting the radiator 5 and the valve 6). , Are provided above and / or below both to generate a magnetic field. By providing the magnets 7 in this manner, the magnetization M of the magnetically functional material is larger in the region inside the radiator 5 than in the region inside the coolant passage 3 outside the radiator 5. As a result, the magnetic body force in the region inside the radiator 5 becomes larger than the magnetic body force in the region inside the coolant flow path 3 outside the radiator 5, and the driving force from the radiator 5 toward the pump 4 (magnetic drive effect). Occurs.

  Therefore, according to the engine cooling device 1B according to the present embodiment, since the flowability of the coolant can be improved by utilizing the magnetic drive effect, a gear pump smaller than that of the first embodiment is used as the pump 4. can do. In addition, depending on the required fluidity, the pump 4 can be omitted, and an engine cooling device without the pump 4 can be realized.

(Motor cooling device)
Next, as a cooling device according to the present embodiment, a motor cooling device for cooling a motor mounted on a vehicle such as an electric vehicle and an inverter for driving the motor will be described.

  FIG. 5 shows a motor cooling device 11B according to the present embodiment. The motor cooling device 11B uses the coolant according to the second embodiment. The motor cooling device 11B changes the position of the radiator 15 of the motor cooling device 11A according to the first embodiment to a position near the upstream side of the inverter 12b, and adds a magnet 17 (corresponding to the “magnetic field generating unit” of the present invention). It was done.

  By arranging the radiator 15 and the inverter 12b in this order along the flow direction of the coolant, the coolant in the radiator 15 is cooled, while the coolant in the inverter 12b is heated by the heat of the inverter 12b. This results in a non-uniform temperature distribution.

  As the magnet 17, for example, as shown in FIG. 3, a pair of permanent magnets having different poles arranged in parallel can be used. The magnet 17 is provided above and / or below both the first region in the radiator 15 and the second region in the inverter 12b adjacent to the first region so as to generate a magnetic field.

  By providing the magnets 17 in this way, the magnetization M of the magnetically functional material is larger in the region inside the radiator 15 than in the region inside the inverter 12b. As a result, the magnetic body force in the region inside the radiator 15 becomes larger than the magnetic body force in the region inside the inverter 12b, and a driving force (magnetic drive effect) from the radiator 15 to the inverter 12b is generated.

  Therefore, according to the motor cooling device 11B according to the present embodiment, since the fluidity of the coolant can be improved by utilizing the magnetic driving effect, a gear pump smaller than that of the first embodiment is used as the pump 14. can do. Further, depending on the required fluidity, the pump 14 can be omitted, and a motor cooling device without a pump can be realized.

  The embodiments of the coolant and the cooling device according to the present invention have been described above, but the present invention is not limited to the above embodiments.

  For example, the configuration, arrangement, and number of the magnets 7, 17 can be changed as appropriate. For example, although a permanent magnet is used in the above embodiment, an electromagnet may be used. Further, in the above embodiment, one magnet 7, 17 is used, but two or more magnets 7, 17 may be used.

  Further, the coolant according to the present invention is a coolant for cooling a prime mover mounted on a vehicle, and contains a polyol ester which is a lubricant oil having a freezing point of −70 ° C. or less without containing ethylene glycol. , The configuration can be changed as appropriate.

  The configuration of the cooling device using the coolant according to the first embodiment can be appropriately changed as long as the device includes a coolant channel and a gear pump. As long as the cooling device using the coolant according to the second embodiment includes a coolant channel, a cooling unit that cools the coolant, and a magnetic field generation unit, the configuration may be changed as appropriate. it can.

1A, 1B Engine cooling device 2 Engine 3 Coolant flow path 4 Pump 5 Radiator 6 Valve 7 Magnet 11A, 11B Motor cooling device 12a Motor 12b Inverter 13 Coolant flow path 14 Pump 15 Radiator 17 Magnet

Claims (7)

A coolant for cooling a prime mover mounted on a vehicle,
Without containing ethylene glycol,
A coolant characterized by containing a polyol ester, which is a lubricating oil having a freezing point of −70 ° C. or less, as a main component. In the polyol ester, a magnetic functional material is dispersed,
2. The coolant according to claim 1, wherein the magnetic functional material has an average particle diameter of 10 μm or less, and has a temperature-sensitive characteristic in which magnetization decreases with increasing temperature in a normal temperature range. A cooling device for cooling a prime mover mounted on a vehicle,
A coolant containing a polyol ester having a freezing point of −70 ° C. or less without containing ethylene glycol,
A coolant passage for circulating the coolant,
A pump for flowing the coolant in the coolant channel,
With
The cooling device, wherein the pump is a gear pump that causes the coolant to flow by a gear. A cooling device for cooling a prime mover mounted on a vehicle,
Without ethylene glycol, contains polyol ester whose lubricating oil has a freezing point of -70 ° C or less, has an average particle size of 10 µm or less, and has a temperature-sensitive property that magnetization decreases with increasing temperature in a normal temperature range. A coolant in which the magnetic functional material is dispersed,
A coolant passage for circulating the coolant,
A cooling unit that is provided in the coolant channel and cools the coolant,
A cooling device, comprising: a magnetic field generator configured to generate a magnetic field in a first region inside the cooling unit and a second region outside the cooling unit adjacent to the first region. Further comprising a pump for flowing the coolant in the coolant channel,
The cooling device according to claim 4, wherein the pump is a gear pump that causes the coolant to flow by a gear. The cooling device according to claim 4, wherein a pump for flowing the coolant in the coolant channel is not provided. The motor comprises the motor and an inverter that drives the motor,
The cooling unit is provided adjacent to the inverter,
The cooling device according to claim 4, wherein the magnetic field generation unit generates a magnetic field in the inverter that is the second region.

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