JPH10195926A - Electric motor cooling device for excavator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric motor cooling device capable of promoting excavating capability without impairing safety of an excavator. SOLUTION: An oil pressure supply source is equipped with an oil cooler 56 and, at the same time, it is equipped with a hydraulic pump driven by an internal combustion engine 28 mounted on an excavator main body 1. The oil cooler 56 is cooled by a fan rotated with the internal combustion engine 28. A driving mechanism 10 for rotating and driving an excavating device 26 is equipped with a liquid-cooled electric motor and, at the same time, operating fluid is supplied to the liquid-cooled electric motor from the oil pressure supply source to cool the liquid-cooled electric motor.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric motor cooling device for an excavator that cools an electric motor of an excavator for excavating a pile hole by rotating an excavator such as an auger drill by an electric motor.

[0002]

2. Description of the Related Art Heretofore, there has been known a method in which a drive mechanism having an electric motor for rotationally driving a drilling tool such as an auger drill is moved up and down along a leader erected on an excavator body to drill a pile hole. ing. As disclosed in JP-A-7-222350, such an excavator has a temperature sensor that detects the temperature of the electric motor in order to protect the electric motor from burnout and the like. An overload protection device is provided for shutting off the circuit when the temperature reaches an allowable temperature.

[0003]

However, in such a conventional apparatus, when a large horsepower is required, such as when the length of a drilling hole is long, the overload protection device is frequently activated, and the electric motor is not operated. Driving may stop. Also, the electric motor is air-cooled by a fan attached to the output shaft of the electric motor.However, if the electric motor is rotated at a low speed by inverter control or the like, the cooling capacity is reduced, and the allowable temperature is quickly reached to reach the allowable temperature. Driving may stop. In such a case, a large capacity electric motor may be used. However, there is a problem in that the electric motor becomes heavy and the stability of the excavator may be impaired.

[0004] It is an object of the present invention to provide an electric motor cooling device for an excavator capable of improving the excavating ability without impairing the stability of the excavator.

[0005]

In order to achieve the above object, the present invention takes the following means to solve the problem. That is, in an excavator that raises and lowers a drive mechanism along a leader erected on an excavator body provided with a hydraulic supply source having an oil cooler and that excavates a pile hole by rotating an excavator by the drive mechanism. The drive mechanism includes a liquid-cooled electric motor, and supplies hydraulic fluid to the liquid-cooled electric motor from the hydraulic supply source to cool the liquid-cooled electric motor.

[0006] The hydraulic supply source may include a hydraulic pump driven by an internal combustion engine mounted on the excavator body, or the excavator body is self-propelled, and the hydraulic supply source includes: The hydraulic oil may be supplied to a traveling hydraulic motor of the excavator body. Further, the oil cooler may be cooled by a fan rotated by the internal combustion engine, or may be cooled by an electric fan.

[0007]

Embodiments of the present invention will be described below in detail with reference to the drawings. As shown in FIG. 1, reference numeral 1 denotes a self-propelled excavator main body.
And A leader 6 is supported on the swivel base 4 by a pair of stays 8 and the like so that the leader 6 can be turned upside down. A guide rail (not shown) is laid on the reader 6 along its longitudinal direction, and a drive mechanism 10 is slidably engaged with the guide rail along the guide rail.

A wire 14 pulled out from a main winch 12 provided on the swivel 4 is wound around a sheave (not shown) rotatably supported on the upper end of the reader 6, and further, a suspension (not shown) of a drive mechanism 10. After being wound around the sheave, it is fastened to the upper end of the reader 6.

As shown in FIG. 3, the drive mechanism 10 includes a liquid-cooled electric motor 16, and the liquid-cooled electric motor 16 includes a cooling jacket 18. The cooling jacket 18 is driven by the cooling medium supplied to the liquid-cooled electric motor 1.
6 for cooling the stator 16a and the like.

The liquid-cooled electric motor 16 has a planetary reducer 20
And the last-stage speed reducer 22 are connected, and the output shaft 24 of the last-stage speed reducer 22 projects downward in parallel with the reader 6. As shown in FIG. 1, a drilling tool 26 such as an auger drill is connected to the output shaft 24.

As shown in FIG. 2, an internal combustion engine 28 is mounted on the swivel 4. The internal combustion engine 28 is connected to drive a pair of main hydraulic pumps 32 and 34 via a speed reducer 30. ing. The internal combustion engine 28 is connected to drive a hydraulic pump 50 via a speed reducer 30.

One main hydraulic pump 32 has a hydraulic tank 35.
It is connected so that hydraulic oil in the inside can be pressurized and hydraulic oil can be supplied to the main winding hydraulic motor 38 and the traveling right hydraulic motor 40 via the switching valve device 36. Hydraulic motor for main winding 38
Is a drive source that drives the main winch 12 to wind and unwind the wire 14, and the traveling right hydraulic motor 40 is a drive source that rotationally drives the right crawler of the traveling mechanism 2.

The other main hydraulic pump 34 is a hydraulic tank 35
The hydraulic oil is pressurized and connected to the auxiliary winding hydraulic motor 44 and the traveling left hydraulic motor 46 via the switching valve device 42 so that the hydraulic oil can be supplied. Hydraulic motor for auxiliary winding 44
Is a drive source that drives the auxiliary winch 48 to wind and unwind a wire (not shown), and the traveling left hydraulic motor 46 is a drive source that rotationally drives the left crawler of the traveling mechanism 2.

The hydraulic pump 50 is connected so as to pressurize hydraulic oil in a hydraulic tank 35 and supply hydraulic oil to a turning hydraulic motor 54 and an oil cooler 56 via a switching valve device 52. The switching valve device 52 normally (when not operated) communicates the hydraulic pump 50 with the oil cooler 56,
When the switching operation is performed, the hydraulic pump 50 and the turning hydraulic motor 54 communicate with each other.

The turning hydraulic motor 54 is a driving source for driving the turning table 4 to turn, and the oil cooler 56 is a drive source for the internal combustion engine 28.
In this configuration, the working oil passing through the oil cooler 56 is cooled by the fan 58 rotated by the fan. In addition, not only the fan 58 rotated by the internal combustion engine 28 but also a configuration in which the operating oil passing through the oil cooler 56 is cooled by the electric fan may be used.

The oil cooler 56 is connected via a hose 59 to the cooling jacket 18 of the liquid-cooled electric motor 16 so as to supply hydraulic oil.
Is connected so that the hydraulic oil passing through the inside can be returned to the hydraulic tank 35 via the hose 60. still,
In the present embodiment, the main hydraulic pumps 32, 34, the hydraulic pump 50, the switching valve devices 36, 42, 52, the oil cooler 56
Constitutes a hydraulic supply source 62.

Next, the operation of the electric motor cooling device for an excavator according to this embodiment will be described. First, when the internal combustion engine 28 is operated, the main hydraulic pumps 32 and 34 and the hydraulic pump 50 are driven via the speed reducer 30, and the hydraulic oil in the hydraulic tank 35 is pressurized and discharged. When the switching valve devices 36 and 42 are switched to supply hydraulic oil to the traveling right hydraulic motor 40 and the traveling left hydraulic motor 46, the crawler rotates and travels.

When the switching valve device 36 is switched to supply hydraulic oil to the main winding hydraulic motor 38, the main winding winch 12 is driven to wind and unwind the wire 14. When the wire 14 is wound up, the drive mechanism 10 moves up along the guide rail, and when the wire 14 is paid out, the drive mechanism 10 moves down along the guide rail.

On the other hand, when hydraulic oil is supplied to the oil cooler 56 through the switching valve device 52, the hydraulic oil is cooled by the fan 58 in the oil cooler 56, and the cooled hydraulic oil is supplied to the liquid-cooled electric motor 16 The cooling jacket 18 is supplied via a hose 59. After cooling the liquid-cooled electric motor 16, the hydraulic oil supplied to the cooling jacket 18 is returned to the hydraulic tank 35 via the hose 60. When the switching valve device 52 is switched to supply hydraulic oil to the turning hydraulic motor 54, the turning hydraulic motor 54 causes the turning table 4 to turn.

When the liquid-cooled electric motor 16 is driven to rotate, the excavator 26 is driven to rotate via the planetary speed reducer 20 and the final-stage speed reducer 22. When the wire 14 is paid out from the main winch 12, the drive mechanism 10 moves down along the guide rail, and the excavation tool 26 excavates the pile hole.

When the liquid-cooled electric motor 16 is driven, the stator 16a and the like generate heat.
Is absorbed by the hydraulic oil that passes through. The hydraulic oil temporarily returns to the hydraulic tank 35, but is switched by the hydraulic pump 50 to the switching valve device 52.
The oil is supplied to the oil cooler 56 through the cooling device and cooled.
Then, the fluid is supplied to the cooling jacket 18 via the hose 59, and the liquid-cooled electric motor 16 is cooled by the circulation of the hydraulic oil.

As described above, since the liquid-cooled electric motor 16 is cooled by the operating oil, when the load is the same, the temperature rise can be made smaller than that of the air-cooled electric motor.
In the case of electric motors of the same weight, the output horsepower can be increased. Therefore, even when the load is large, the driving mechanism 1
The excavator 26 can be driven to rotate without increasing the weight of the excavator 0, and the excavating ability can be improved without impairing the stability of the excavator.

The oil cooler 56 of the hydraulic supply source 62 provided in the excavator body 1 has a maximum load such as a winch, running, turning, or the like, or a maximum load when these are used at the same time. A fluid having the ability to prevent the temperature of the working oil from rising above the allowable temperature is used. When the excavator 26 is excavated by rotating the excavator 26, it does not travel or turn at the same time, and the main winding winch 12 is also in the direction in which the wire 14 is fed out, so that the temperature rise of the hydraulic oil is very small. .

Therefore, during excavation, the liquid-cooled electric motor 1
The heat generated by the oil cooler 56 is mainly used to increase the temperature of the hydraulic oil, and most of the cooling capacity of the oil cooler 56 is used for cooling the hydraulic oil. Therefore, the hydraulic power source 62 provided in the excavator body 1 is used to cool the liquid-cooled electric motor 16 using the hydraulic oil as a cooling medium, so that there is no need to provide a special new cooling medium supply source. The liquid-cooled electric motor 16 can be cooled with a simple configuration.

In the present embodiment, the hydraulic oil is supplied to the cooling jacket 18 after passing through the oil cooler 56. However, the hydraulic oil that has passed through the oil cooler 56 is once returned to the hydraulic tank 35, The hydraulic oil may be supplied to the cooling jacket 18 by a pump.

Even when the excavator 26 is driven at a low speed, such as during inverter control of the liquid-cooled electric motor 16, hydraulic oil is supplied to the cooling jacket 18 regardless of the rotation speed of the liquid-cooled electric motor 16. Since it is supplied, the liquid-cooled electric motor 16 can be sufficiently cooled even during low-speed rotation.

Further, since the oil cooler 56 is cooled by the fan 58 of the internal combustion engine 28, when the rotation speed of the internal combustion engine 28 is increased, the cooling capacity of the oil cooler 56 is increased. Therefore, when the load is large and the temperature of the liquid-cooled electric motor 16 approaches the allowable temperature, it is easy to perform control to increase the rotation speed of the internal combustion engine 28.

The present invention is not limited to such an embodiment at all, and can be implemented in various forms without departing from the gist of the present invention.

[0029]

As described in detail above, the electric motor cooling system for an excavator according to the present invention cools a liquid-cooled electric motor with hydraulic oil supplied from a hydraulic supply source, thereby impairing the stability of the excavator. There is an effect that the excavation ability can be improved without the need. In addition, since the liquid-cooled electric motor is cooled by using the hydraulic oil provided in the excavator body and using the hydraulic oil as a cooling medium, it is not necessary to provide a new cooling medium supply source, and the configuration is simple. Liquid cooled electric motor can be cooled. Moreover, such as when controlling the inverter of a liquid-cooled electric motor,
Even when the excavator is driven at a low speed, the hydraulic oil is supplied regardless of the rotation speed of the liquid-cooled electric motor, so that the liquid-cooled electric motor can be sufficiently cooled even at a low speed.

Further, when the oil cooler is cooled by a fan of the internal combustion engine, control may be performed to increase the rotation speed of the internal combustion engine when the temperature of the liquid-cooled electric motor approaches the allowable temperature. Easy.

[Brief description of the drawings]

FIG. 1 is a side view of an excavator using an electric motor cooling device for an excavator as one embodiment of the present invention.

FIG. 2 is a hydraulic circuit diagram of the electric motor cooling device for an excavator according to the embodiment.

FIG. 3 is an enlarged side view showing a cross section of a part of the liquid-cooled electric motor of the embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Excavator main body 2 ... Traveling mechanism 4 ... Revolving table 6 ... Leader 10 ... Drive mechanism 16 ... Liquid-cooled electric motor 18 ... Cooling jacket 26 ... Excavator 28 ... Internal combustion engine 35 ... Hydraulic tank 50 ... Hydraulic pump 56 ... Oil Cooler 58 ... Fan 62 ... Hydraulic supply

Claims (5)

[Claims] 1. A drive mechanism is moved up and down along a leader erected on an excavator body provided with a hydraulic supply source having an oil cooler, and a drilling tool is rotationally driven by the drive mechanism to excavate a pile hole. In the excavator, the drive mechanism includes a liquid-cooled electric motor, and supplies hydraulic fluid from the hydraulic supply source to the liquid-cooled electric motor to cool the excavator. 2. The electric motor cooling system for an excavator according to claim 1, wherein the hydraulic supply source includes a hydraulic pump driven by an internal combustion engine mounted on the excavator body. 3. The excavator main body is self-propelled, and the hydraulic supply source supplies hydraulic oil to a traveling hydraulic motor of the excavator main body. Electric motor cooling device for excavator. 4. The electric motor cooling device for an excavator according to claim 1, wherein the oil cooler is cooled by a fan rotated by the internal combustion engine. 5. The electric motor cooling device for an excavator according to claim 1, wherein the oil cooler is cooled by an electric fan.