The present disclosure relates to a gear spindle device for a rolling mill, a rolling mill facility, and a method of cooling a gear spindle device for a rolling mill.
In a rolling mill facility for rolling a steel plate or the like, a spindle is provided between a motor and a mill roll in order to transmit the driving force of the motor to the mill roll. As such a spindle, in some cases, a gear-type spindle using a gear (gear spindle device) is used.
Patent Document 1 discloses a gear spindle including a spindle outer cylinder having an end portion connected to an output shaft or the like of a motor or a gear box and a spindle inner cylinder fitted with the spindle outer cylinder at an end portion opposite to the output shaft described above. At the fitting portion between the spindle outer cylinder and the spindle inner cylinder, an inner gear (inner circumferential gear) is provided for the spindle outer cylinder, and an outer gear (outer circumferential gear) is provided for the spindle inner cylinder so as to engage with the inner gear of the spindle outer cylinder. The torque from the motor is transmitted between the spindle outer cylinder and the spindle inner cylinder via the engaging portion between the inner gear and the outer gear. Furthermore, a lubricant oil chamber sealing a lubricant oil for lubricating the engagement portion between the inner gear and the outer gear described above is formed between the spindle outer cylinder and the spindle inner cylinder at the fitting portion, and the lubricant oil chamber is isolated from the exterior space by a seal member.
Meanwhile, heat is generated from friction or the like at the engaging portion between the inner circumferential gear and the outer circumferential gear of a gear spindle, and thus the gear spindle device may be cooled using a coolant in order to suppress deterioration of the performance of the lubricant oil or wear of the seal member due to the heat, for instance. However, depending on the manner of cooling, the coolant may scatter and cause a negative influence on devices disposed in the vicinity of the gear spindle device or the material to be rolled.
In view of the above, an object of at least one embodiment of the present invention is to provide a gear spindle device or a rolling mill, a rolling mill facility, and a method of cooling a gear spindle device for a rolling mill capable of reducing the negative influence on the devices or the material to be rolled due to supply of the coolant.
According to at least one embodiment of the present invention, a gear spindle device for a rolling mill includes: a spindle outer cylinder having, at a first end side, an inner circumferential surface provided with an inner circumferential gear; a spindle inner cylinder having an outer circumferential surface provided with an outer circumferential gear which engages with the inner circumferential gear; a seal member disposed between the spindle outer cylinder and the spindle inner cylinder, for holding a lubricant oil at an engagement portion between the inner circumferential gear and the outer circumferential gear; and a coolant supply unit disposed at an opposite side to the seal member across the engagement portion in an axial direction of the spindle outer cylinder, for supplying a coolant toward the spindle outer cylinder in a formation region of the engagement portion where the engagement portion is formed.
According to at least one embodiment of the present invention, a rolling mill facility includes: a mill roll; a motor for driving the mill roll; and the gear spindle device described above configured to transmit a rotational driving force generated by the motor to the mill roll.
According to at least one embodiment of the present invention, a method for cooling a gear spindle device for a rolling mill including: a spindle outer cylinder having, at a first end side, an inner circumferential surface provided with an inner circumferential gear; a spindle inner cylinder having an outer circumferential surface provided with an outer circumferential gear which engages with the inner circumferential gear; and a seal member disposed between the spindle outer cylinder and the spindle inner cylinder, for holding a lubricant oil at an engagement portion between the inner circumferential gear and the outer circumferential gear, includes a step of supplying a coolant toward the spindle outer cylinder in a formation region of the engagement portion from a position at an opposite side to the seal member across the engagement portion where the engagement portion is formed in an axial direction of the spindle outer cylinder.
According to at least one embodiment of the present invention, it is possible to provide a gear spindle device or a rolling mill, a rolling mill facility, and a method of cooling a gear spindle device for a rolling mill capable of reducing negative the influence on the devices and the material to be rolled due to supply of the coolant.
Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It is intended, however, that unless particularly identified, dimensions, materials, shapes, relative positions and the like of components described in the embodiments shall be interpreted as illustrative only and not intended to limit the scope of the present invention.
The pair of mill rolls 6 are disposed so as to sandwich the material to be rolled, and supported rotatably on a housing (not depicted) via an axle box (not depicted) disposed on axial end portions 6a, 6b of the mill roll 6. Although not depicted, the rolling mill facility 1 may further include a pair of backup rolls disposed so as to sandwich the pair of mill rolls 6. The pair of backup rolls may be rotatably supported on the above described housing via an axle box disposed on the axial end portions of the backup roll.
The pair of gear spindle devices 10 are configured to transmit the rotary driving force generated by the motor 2 to each of the pair of mill rolls 6.
Each of the pair of the gear spindle devices 10 includes a middle shaft 12, a spindle inner cylinder 14A and a spindle outer cylinder 16A disposed on an end portion of the middle shaft 12 at the side of the motor 2, and a spindle inner cylinder 14B and a spindle outer cylinder 16B disposed on an end portion of the middle shaft 12 at the side of the mill roll 6.
The middle shaft 12 of the gear spindle device 10 is coupled to the output shaft of the device at the side of the motor 2 via the spindle inner cylinder 14A and the spindle outer cylinder 16A. In the illustrative embodiment shown in the drawing, a gear box (transmission) 4 is disposed between the motor 2 and the gear spindle device 10. The middle shaft 12 is coupled to the output shaft 5 of the gear box 4 via the spindle inner cylinder 14A and the spindle outer cylinder 16A. The gear box 4 is configured to shift the rotation speed of the rotary driving force generated by the motor 2, and divide the rotary driving force into two. In another embodiment, a motor for driving the mill roll 6 may be connected to the gear spindle device 10 not via the gear box. That is, the middle shaft 12 of the gear spindle device 10 may be coupled to the output shaft of the motor via the spindle inner cylinder 14A and the spindle outer cylinder 16A.
Furthermore, the middle shaft 12 of the gear spindle device 10 is coupled to the axial end portion 6a of the mill roll 6 via the spindle inner cylinder 14B and the spindle outer cylinder 16B.
As depicted in
A lubricant oil is supplied to the engagement portion 22 between the inner circumferential gear 30 of the spindle outer cylinder 16A and the outer circumferential gear 26 of the spindle inner cylinder 14A, via a non-depicted lubricant oil supply passage. A lubricant oil chamber 32 which stores the above described lubricant oil is formed between the inner circumferential surface 28 of the spindle outer cylinder 16A and the outer circumferential surface 24 of the spindle inner cylinder 14A. Furthermore, a seal member 34 for holding the lubricant oil at the engagement portion 22 (that is, for suppressing leakage of the lubricant oil from the lubricant oil chamber 32) is disposed between the inner circumferential surface 28 of the spindle outer cylinder 16A and the outer circumferential surface 24 of the spindle inner cylinder 14A.
As depicted in
In the rolling mill facility 1 configured as described above, the rotary driving force generated by the motor 2 is transmitted to mill rolls 6 via the output shaft at the side of the motor 2, the spindle outer cylinder 16A and the spindle inner cylinder 14A at the side of the motor 2 including the engagement portion 22, the middle shaft 12, and the spindle outer cylinder 16B and the spindle inner cylinder 14B at the side of the mill rolls 6 including the engagement portion.
Next, the gear spindle device 10 according to some embodiments will be described in more detail. As depicted in
In the following description, the spindle inner cylinders 14A and 14B will be collectively referred to as the spindle inner cylinder 14, the spindle outer cylinders 16A and 16B will be collectively referred to as the spindle outer cylinder 16, and the coolant supply units 18A and 18B will be collectively referred to as the coolant supply unit 18. Furthermore, in the following description, the gear spindle device 10 according to some embodiments will be described referring mainly to the drawings showing a portion of the gear spindle device 10 including the spindle outer cylinder 16A and the coolant supply unit 18A at the side of the motor 2. Nevertheless, a similar description is applicable to the side of the mill rolls 6.
As depicted in
According to the above embodiment, it is possible to supply the coolant toward the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22 from the coolant supply unit 18 disposed at the opposite side to the seal member 34 across the engagement portion 22 between the inner circumferential gear 30 and the outer circumferential gear 26 disposed at the side of the first end 16a of the spindle outer cylinder 16 (that is, the side opposite to the second end 16b engaged with the output shaft of the motor 2 or the gear box 4 or the axial end portion 6a of the mill roll 6). Thus, it is possible to effectively suppress scattering of the coolant discharged toward the spindle outer cylinder 16 from the coolant supply unit 18, or the coolant discharged accordingly and bounced back at the surface of the spindle outer cylinder 16 toward the devices (e.g., the gear box 4, the motor 2, or the mill rolls 6) coupled to the second end 16b side of the spindle outer cylinder 16. Thus, it is possible to reduce the negative influence on the devices or the material to be rolled due to supply of the coolant.
For instance, by providing the coolant supply unit 18A for supplying the coolant toward the spindle outer cylinder 16A at the side of the motor 2 of the gear spindle device 10, it is possible to suppress breakdown of the gear box 4 or the motor 2 due to incorporation of the coolant. Alternatively, by providing the coolant supply unit 18B for supplying the coolant toward the spindle outer cylinder 16B at the side of the mill rolls 6 of the gear spindle device 10, it is possible to suppress failure in the temperature management of the material to be rolled due to adhesion of the coolant to the material to be rolled, for instance.
In some embodiments, as depicted in
In the illustrative embodiment depicted in
It should be noted that the upper side and the lower side in the present specification refer to the upper side and the lower side in the vertical direction (top-bottom direction).
In the illustrative embodiment depicted in
According to the above described embodiment, the spindle outer cylinder 16 and the coolant supply unit 18 in the formation region A1 of the engagement portion 22 are housed inside the housing 20, and thus it is possible to effectively suppress scattering of the coolant to the devices (i.e., the motor 2 and the gear box 4) coupled to the spindle outer cylinder 16 at the side of the second end 16b.
In some embodiments, the housing 20 includes a first wall portion having a hole into which a shaft fitting to the spindle outer cylinder 16 at the side of the second end 16b of the spindle outer cylinder 16 in the axial direction is inserted, and the hole has a smaller diameter than the spindle outer cylinder 16. In the illustrative embodiment depicted in
According to the above embodiment, the diameter D3 of the hole 43 disposed on the axial-direction end wall portion 42 (first wall portion) of the housing 20, into which the output shaft 5 of the gear box 4 fitting to the spindle outer cylinder 16 is inserted, is smaller than the diameter D1 of the spindle outer cylinder 16, and thus it is possible to effectively suppress scattering of the coolant to the gear box4.
In some embodiments, as depicted in
According to the above described embodiment, the coolant supply unit 18 injects the coolant toward the spindle outer cylinder 16 from the position above the spindle outer cylinder 16, and thus the injected coolant reaches the spindle outer cylinder 16 more reliably, compared to a case where the coolant is injected toward the spindle outer cylinder 16 from a position below the spindle outer cylinder 16. Thus, it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b, while effectively cooling the cooling target portion (the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22) of the gear spindle device 10.
In the illustrative embodiment depicted in
According to the above described embodiment, the coolant supply unit 18 includes the nozzle 19, and thus it is easier to adjust the injection angle of the coolant from the nozzle 19 and the supply range of the coolant to the spindle outer cylinder 16. Thus, it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b, while cooling the cooling target portion of the gear spindle device 10 effectively.
In some embodiments, as depicted in
In some embodiments, as depicted in
According to the above-described embodiment, with the nozzle 19 (coolant supply unit 18), the coolant is injected in a direction from the second end 16b (the side where the devices are coupled) toward the first end 16a (the side where the spindle inner cylinder 14 is disposed) of the spindle outer cylinder 16, and thus it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b.
In some embodiments, as depicted in
According to the embodiment, the nozzle 19 (the coolant supply unit 18) supplies the coolant toward the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22 from a position farther from the seal member 34 in the axial direction than the supply region A2 of the coolant, and thus it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b.
In some embodiments, when the spindle outer cylinder 16 is seen in a horizontal direction which is orthogonal to the center axis O of the spindle outer cylinder 16 (see
According to the above described embodiment, the above described angular degree α is not smaller than 30 degrees and not greater than 60 degrees, and thus it is possible to ensure a large contact area between the spindle outer cylinder 16 and the coolant. Thus, it is possible to cool the cooling target portion of the gear spindle device 10 effectively. Furthermore, if the above described angular degree is not greater than 60 degrees, the coolant injected from the nozzle 19 and bounced back on the surface of the spindle outer cylinder 16 is more likely to be oriented in a direction from the second end 16b (the side where the devices are coupled) toward the first end 16a (the side where the spindle inner cylinder 14 is disposed) of the spindle outer cylinder 16. Thus, it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b.
In some embodiments, when the spindle outer cylinder 16 is seen in the axial direction (see
According to the above described embodiment, the above described angular degree β is not smaller than 30 degrees and not greater than 60 degrees, and thus it is possible to ensure a large contact area between the spindle outer cylinder 16 and the coolant. Thus, it is possible to cool the cooling target portion of the gear spindle device 10 effectively.
In some embodiments, when the spindle outer cylinder 16 is seen in a planar view (see
According to the above described embodiment, the above described angular degree γ is not smaller than 30 degrees and not greater than 60 degrees, and thus it is possible to ensure a large contact area between the spindle outer cylinder 16 and the coolant. Thus, it is possible to cool the cooling target portion of the gear spindle device 10 effectively.
As depicted in
According to the above described embodiment, it is possible to measure the temperature of the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22 with the temperature sensor 52, and thus it is possible to confirm if the cooling target portion (i.e., the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22) is cooled appropriately on the basis of the temperature measured by the temperature sensor 52. Thus, it is possible to suppress scattering of the coolant toward the devices (the gear box 4 or the mill rolls 6, for instance) coupled to the spindle outer cylinder 16 at the side of the second end 16b effectively, while cooling the cooling target portion of the gear spindle device 10 more reliably.
In some embodiments, as depicted in
According to the above described embodiment, the temperature sensor 52 is disposed at a position offset from the coolant supply unit 18 in a direction from the second end 16b toward the first end 16a of the spindle outer cylinder 16 in the axial direction, and thus it is possible to measure the temperature in the vicinity of the portion of the spindle outer cylinder 16 to which the coolant is supplied (the formation region A1 of the engagement portion 22) with the temperature sensor 52. Thus, it is possible to check if the cooling target portion is appropriately cooled more accurately, on the basis of the temperature measured by the temperature sensor 52.
In some embodiments, the temperature sensor 52 is configured to measure the temperature of the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22 using infrared light. That is, the temperature sensor 52 has a light receiving portion for receiving infrared light discharged from the spindle outer cylinder 16 in the formation region A1 of the engagement portion 22, and is configured to obtain the temperature of the above described spindle outer cylinder 16 on the basis of the detection result of infrared light obtained by the light receiving portion.
In some embodiments, as depicted in
In the above described embodiment, the above described pipe 56 is disposed between the temperature sensor 52 and the spindle outer cylinder 16, and thus the pipe 56 prevents the coolant discharged from the coolant supply unit 18 or the coolant bounced back at the spindle outer cylinder 16 from reaching the temperature sensor 52, which makes it easier to ensure a path of infrared light between the temperature sensor 52 and the spindle outer cylinder 16. Thus, it is possible to measure the temperature of the spindle outer cylinder 16 more accurately with the temperature sensor 52.
In some embodiments, as depicted in
In the above described embodiment, with the gas supply part 58, it is possible to form a gas flow flowing from the temperature sensor 52 toward the spindle outer cylinder 16 inside the pipe 56. Accordingly, the coolant discharged from the coolant supply unit 18 or the coolant bounced back at the spindle outer cylinder 16 is less likely to enter the inside of the pipe 56. Furthermore, even if the coolant enters the inside of the pipe 56, it is possible to let the coolant out the pipe 56 with the above described gas flow. Thus, it is possible to measure the temperature of the spindle outer cylinder 16 more accurately with the temperature sensor 52.
In some embodiments, as depicted in
In the illustrative embodiment depicted in
According to the above described embodiment, the temperature sensor 52 is supported by the lid portion 50 capable of opening and closing the opening portion 47 disposed on the housing 20, and thus it is possible to perform maintenance on the temperature sensor 52 together when performing maintenance on the gear spindle device 10 by opening the opening portion 47. Thus, it is possible to perform maintenance efficiently on the gear spindle device 10, where the coolant is supplied to the spindle outer cylinder 16.
In an embodiment, in addition to the temperature sensor 52, the above described pipe 56 and/or the gas supply part 58 may be supported on the lid portion 50.
In an embodiment, as depicted in
In an embodiment, as depicted in
Accordingly, by supporting the pipe 56 and/or the gas supply part 58 with the lid portion 50, it is possible to perform maintenance on the pipe 56 and/or the gas supply part 58 together when performing maintenance on the gear spindle device 10 by opening the opening portion 47. Thus, it is possible to perform maintenance efficiently on the gear spindle device where the coolant is supplied to the spindle outer cylinder 16.
In an embodiment, the gas supply pipe of the gas supply part 58 may be formed of a flexible material. In this case, the gas supply pipe has flexibility, and thus it is possible to open and close the lid portion 50 easily without removing the gas supply pipe.
In some embodiments, as depicted in
With the above configuration, the arm 66, 68 for connecting the lid portion 50 and the lateral wall portion 46 (second wall portion), and the hinge 67, 69, 71 for supporting the arm 66, 68 on the lid portion 50 or the lateral wall portion 46 (second wall portion) rotatably are provided, and thus it is possible to easily open and close the lid portion 50 having an increased weight from supporting the temperature sensor 52.
The coolant circulation device 80 depicted in
The coolant circulation device 80 includes a tank 82 for storing the coolant. The coolant collected by the coolant receiving portion 94 is guided to the tank via a tank introduction line 96.
The coolant circulation device 80 includes a first temperature adjustment part 84 for adjusting the temperature of the coolant inside the tank 82 to the temperature suitable for cooling the mill roll 6. The first temperature adjustment part 84 may include a heater for heating the coolant inside the tank 82. The coolant inside the tank 82 having a temperature adjusted by the first temperature adjustment part 84 is pumped to the first supply line 90 and the second supply line 88 via the pump 86.
The coolant circulation device 80 includes a second temperature adjustment part 92 for adjusting the temperature of the coolant flowing through the first supply line 90 to the temperature suitable for cooling the spindle outer cylinder 16. The second temperature adjustment part 92 may include a cooler for cooling the coolant flowing through the first supply line 90. The first supply line 90 includes a branch line 90a and a branch line 90b. The coolant whose temperature is adjusted by the second temperature adjustment part 92 is supplied to the coolant supply unit 18A for cooling the spindle outer cylinder 16A at the side of the motor 2 via the branch line 90a, and to the coolant supply unit 18B at the side of the mill roll 6 via the branch line 90b.
The coolant supplied to the mill roll 6 and the coolant supplied to the spindle outer cylinder 16 are each collected to the coolant receiving portion 94 via a non-depicted path. The coolant supplied to the spindle outer cylinder 16 may be guided to the coolant receiving portion 94 via a discharge port 98 disposed on the housing 20 and a drain pipe (not depicted) connected to the discharge port 98.
According to the above described embodiment, the coolant supplied to each of the spindle outer cylinder 16 and the mill roll 6 is collected by the coolant receiving portion 94, and the coolant is supplied to the coolant supply unit 18 via the first supply line 90 and to the mill roll 6 via the second supply line 88, respectively. That is, in the above described embodiment, the coolant supplied to the spindle outer cylinder 16 is also used as the coolant supplied to the mill roll 6. Thus, compared to a case where the cooling mechanism for the spindle outer cylinder 16 and the coolant mechanism for the mill roll 6 are provided separately, it is possible to effectively suppress scattering of the coolant toward the devices (the gear box 4 or the mill roll 6, for instance) coupled to the side of the second end 16b of the spindle outer cylinder 16 while reducing the installation space and cost of the devices.
Hereinafter, a gear spindle device for a rolling mill, a rolling mill facility, and a method of cooling a gear spindle device for a rolling mill according to some embodiments will be described in summary.
According to the above configuration (1), the coolant is supplied toward the spindle outer cylinder in the formation region of the engagement portion from the coolant supply unit disposed at the opposite side to the seal member across the engagement portion between the inner circumferential gear and the outer circumferential gear disposed at the side of the first end of the spindle outer cylinder, and thus it is possible to effectively suppress scattering of the coolant toward the devices (e.g., the gear box, the motor, or the mill rolls) coupled to the second end side of the spindle outer cylinder. Thus, it is possible to reduce the negative influence on the devices or the material to be rolled due to supply of the coolant. For instance, it is possible to suppress breakdown of the gear box or the motor due to intrusion of the coolant, failure in temperature management of the material to be rolled due to adhesion of the coolant to the material to be rolled, and the like.
According to the above configuration (2), the spindle outer cylinder and the coolant supply unit in the formation region of the engagement portion is housed inside the housing, and thus it is possible to effectively suppress scattering of the coolant to the devices coupled to the second end side of the spindle outer cylinder.
According to the above configuration (3), the diameter of the hole which is disposed on the first wall portion of the housing and into which the shaft fitting to the spindle outer cylinder (e.g., the output shaft of the motor or the gear box, for instance) is inserted is smaller than the diameter of the spindle outer cylinder, and thus it is possible to effectively suppress scattering of the coolant to devices including the above described shaft.
According to the above configuration (4), the coolant supply unit injects the coolant toward the spindle outer cylinder from a position above the spindle outer cylinder, and thus the injected coolant reaches the spindle outer cylinder more reliably, compared to a case where the coolant is injected toward the spindle outer cylinder from a position below the spindle outer cylinder. Thus, it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder, while effectively cooling the cooling target portion of the gear spindle device.
According to the above configuration (5), the coolant supply unit includes the nozzle, and thus it is easier to adjust the injection angle of the coolant from the nozzle and the supply range of the coolant to the spindle outer cylinder. Thus, it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder, while effectively cooling the cooling target portion of the gear spindle device.
According to the above configuration (6), with the nozzle, the coolant is injected in a direction from the second end (the side where the devices are coupled) toward the first end (the side where the spindle inner cylinder is disposed) of the spindle outer cylinder, and thus it is possible to suppress scattering of the coolant toward the devices coupled to the spindle outer cylinder at the side of the second end more effectively. Thus, it is possible to reduce the negative influence on the devices or the material to be rolled due to supply of the coolant.
According to the above configuration (7), when the spindle outer cylinder is seen in a horizontal direction which is orthogonal to the center axis of the spindle outer cylinder, the angular degree formed between the center axis of the nozzle and the center axis of the spindle outer cylinder is not smaller than 30 degrees and not greater than 60 degrees, and thus it is easier to ensure a large contact area between the spindle outer cylinder and the coolant. Thus, it is possible to cool the cooling target portion of the gear spindle device effectively. Furthermore, if the above described angular degree is not greater than 60 degrees, the coolant injected from the nozzle and bounced back on the surface of the spindle outer cylinder is more likely to be oriented in a direction from the second end (the side where the devices are coupled) toward the first end (the side where the spindle inner cylinder is disposed) of the spindle outer cylinder. Thus, it is possible to suppress scattering of the coolant toward the devices coupled to the spindle outer cylinder at the side of the second end more effectively. Thus, according to the above configuration (7), it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder, while effectively cooling the cooling target portion of the gear spindle device.
According to the above configuration (8), when the spindle outer cylinder is seen in the axial direction, the angular degree formed between the center axis of the nozzle and the horizontal direction is not smaller than 30 degrees and not greater than 60 degrees, and thus it is possible to ensure a large contact area between the spindle outer cylinder and the coolant. Thus, it is possible to cool the cooling target portion of the gear spindle device effectively. Thus, according to the above configuration (8), it is possible to effectively suppress scattering of the coolant toward the devices coupled to second end side of the spindle outer cylinder, while effectively cooling the portion to be cooled of the gear spindle device.
According to the above configuration (9), it is possible to measure the temperature of the spindle outer cylinder in the formation region of the engagement portion with the temperature sensor, and thus it is possible to confirm if the cooling target portion is cooled appropriately on the basis of the temperature measured by the temperature sensor. Thus, it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder, while cooling the cooling target portion of the gear spindle device even more reliably.
According to the above configuration (10), the temperature sensor is disposed at a position offset from the coolant supply unit in a direction from the second end toward the first end of the spindle outer cylinder in the axial direction, and thus it is possible to measure the temperature in the vicinity of the portion of the spindle outer cylinder to which the coolant is supplied with the temperature sensor. Thus, it is possible to check if the cooling target portion is appropriately cooled, on the basis of the measured temperature. Thus, it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder, while cooling the cooling target portion of the gear spindle device even more reliably.
According to the above configuration (11), the temperature sensor is supported by the lid portion capable of opening and closing the opening portion provide for the housing, and thus it is possible to perform maintenance on the temperature sensor together when performing maintenance on the gear spindle device by opening the opening portion. Thus, it is possible to perform maintenance efficiently on the gear spindle device, where the coolant is supplied to the spindle outer cylinder.
According to the above configuration (12), the arm for connecting the lid portion and the second wall portion and the hinge for supporting the arm on the lid portion or the second wall portion rotatably are provided, and thus it is possible to easily open and close the lid portion having an increased weight from supporting the temperature sensor.
According to the above configuration (13), the coolant is supplied toward the spindle outer cylinder in the formation region of the engagement portion from the coolant supply unit disposed at the opposite side to the seal member across the engagement portion between the inner circumferential gear and the outer circumferential gear disposed at the first end side of the spindle outer cylinder, and thus it is possible to effectively suppress scattering of the coolant toward the devices (e.g., the gear box, the motor, or the mill rolls) coupled to the second end side of the spindle outer cylinder. Thus, it is possible to reduce the negative influence on the devices or the material to be rolled from supply of the coolant. For instance, it is possible to suppress breakdown of the gear box or the motor due to intrusion of the coolant, failure in temperature management of the material to be rolled due to adhesion of the coolant to the material to be rolled, and the like.
According to the above configuration (14), the coolant circulation device is provided, and the coolant collected by the coolant receiving portion is supplied to the coolant supply unit via the first supply line and to the mill roll via the second supply line, respectively. That is, according to the above configuration (14), the coolant supplied to the spindle outer cylinder is also used as the coolant supplied to the mill roll. Thus, compared to a case where the cooling mechanism for the spindle outer cylinder and the coolant mechanism for the mill roll are provided separately, it is possible to effectively suppress scattering of the coolant toward the devices coupled to the second end side of the spindle outer cylinder while reducing the installation space and cost of the devices.
According to the above method (15), the coolant is supplied toward the spindle outer cylinder in the formation region of the engagement portion from a position at the opposite side to the seal member across the engagement portion of the inner circumferential gear and the outer circumferential gear disposed at the side of the first end of the spindle outer cylinder, and thus it is possible to effectively suppress scattering of the coolant toward the devices (e.g., the gear box, the motor, or the mill rolls) coupled to the second end side of the spindle outer cylinder. Thus, it is possible to reduce the negative influence on the devices or the material to be rolled due to supply of the coolant. For instance, it is possible to suppress breakdown of the gear box or the motor due to intrusion of the coolant, failure in temperature management of the material to be rolled due to adhesion of the coolant to the material to be rolled, and the like.
Embodiments of the present invention were described in detail above, but the present invention is not limited thereto, and various amendments and modifications may be implemented.
Further, in the present specification, an expression of relative or absolute arrangement such as “in a direction”, “along a direction”, “parallel”, “orthogonal”, “centered”, “concentric” and “coaxial” shall not be construed as indicating only the arrangement in a strict literal sense, but also includes a state where the arrangement is relatively displaced by a tolerance, or by an angle or a distance whereby it is possible to achieve the same function.
For instance, an expression of an equal state such as “same” “equal” and “uniform” shall not be construed as indicating only the state in which the feature is strictly equal, but also includes a state in which there is a tolerance or a difference that can still achieve the same function.
Further, for instance, an expression of a shape such as a rectangular shape or a cylindrical shape shall not be construed as only the geometrically strict shape, but also includes a shape with unevenness or chamfered corners within the range in which the same effect can be achieved.
On the other hand, an expression such as “comprise”, “include”, “have”, “contain” and “constitute” are not intended to be exclusive of other components.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/042838 | 11/17/2020 | WO |