JP7490541B2 - Power unit for hydraulic elevator and motor centering method - Google Patents

Description

The present invention relates to a power unit for a hydraulic elevator and a method for centering the motor.

JP 2014-7933 A (Patent Document 1) discloses an adjustment centering jig for rotating equipment and driving machines, etc. In the abstract of Patent Document 1, it is described that in conventional centering work for rotating equipment and driving machines, etc., many devices are not equipped with centering jigs, and that hammer strikes are used to correct centering accuracy. In this case, it is described that the centering work requires a skilled worker, there is a concern that the hammer strikes may damage the equipment or cause sparks, and it is difficult to make corrections in 0.01 mm increments using hammer strikes, etc.

The summary of Patent Document 1 also describes how the centering jig can be installed on the fixed base of the drive unit, using existing screw holes for fixing the drive unit, etc., how the height, length and direction of operation of the centering jig can be changed by rearranging the parts, etc., how these functions and the mounting position of the centering jig can be changed to simultaneously achieve horizontal eccentricity accuracy and parallel accuracy of the rotating equipment and drive unit, etc., and how the centering jig can be installed in the axial direction to adjust the gap between the shaft couplings of the rotating equipment, drive unit, etc.

JP 2014-7933 A

The centering jig in Patent Document 1 discloses a technology in which the centering jig is installed on a base (fixed base) to which a motor or other device (driver or other device) is fixed, utilizing existing screw holes for fixing the motor or other device, and centering adjustments are performed on the motor or other device. The conventional technology disclosed in Patent Document 1 sequentially adjusts the horizontality, eccentricity, height, and gap between the couplings of the motor and rotating device while rearranging the parts and changing the mounting positions on the centering jig. For this reason, centering adjustments take time.

In hydraulic elevators, the pump and motor are connected by a coupling during the assembly of the power unit. In other words, hydraulic elevators are equipped with a pump as a rotating device connected to the motor, and the centering of the pump and motor is adjusted.

In the renewal work of a hydraulic elevator, if the delivery path is narrow and the power unit of the hydraulic elevator cannot be delivered in an assembled state, it is necessary to assemble the power unit on-site. In this case, as described in Patent Document 1, if the levelness, eccentricity, height, and gap between the couplings of the motor and the pump are adjusted in sequence while rearranging the parts and changing the mounting positions in the centering jig, the centering adjustment requires a long work time, and is not suitable for on-site situations where early completion of the work is desired, such as renewal work.
The present invention has been made in consideration of the above-mentioned points, and an object of the present invention is to provide a power unit and motor centering method for a hydraulic elevator, which makes it possible to adjust the parallelism of the mutual centers of the motor and pump, the horizontal centering misalignment (eccentricity), and the gap between the couplings in a short time, without the need to rearrange parts or change the mounting positions of the centering jig.

In order to solve the above problems, the power unit for a hydraulic elevator of the present invention comprises:
In a hydraulic elevator power unit, which adjusts the mutual center of the motor and pump of the hydraulic elevator power unit,
a motor centering shaft attached to a base that fixes the motor to four corners of the motor;
an axial parallel direction adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial parallel direction along the motor shaft;
a vertical axis adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in a vertical axis direction perpendicular to the motor shaft and in a horizontal direction;
Equipped with
The motor includes a support leg fixed to the base;
The axial parallel direction adjustment bolts include four bolts abutting on both ends of the support legs in the axial parallel direction,
The axial vertical adjustment bolts are made of four bolts abutting against both outer ends of the support legs in the axial vertical direction,
The motor centering is performed by
a first block portion on which the shaft vertical direction adjustment bolt and the fixing bolt are provided for the motor centering, a second block portion on which the shaft parallel direction adjustment bolt and the holding bolt are provided, and a third block portion are integrally formed;
the base includes a pedestal to which the support legs of the motor are fixed, and erected portions erected on both sides in a direction perpendicular to the axis,
the block body is fixed to the base by sandwiching the erected portion between the fixing bolt provided on the first block portion and the third block portion,
The second block portion is fixed to the base by sandwiching the base between the pressing bolt and the third block portion .
In order to solve the above problems, a method for centering a motor of a power unit for a hydraulic elevator includes the steps of:
A hydraulic elevator power unit that adjusts the mutual center of a motor and a pump of the hydraulic elevator power unit ,
a motor centering shaft attached to a base that fixes the motor to four corners of the motor;
an axial parallel direction adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial parallel direction along the motor shaft;
and an axial vertical adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial vertical direction perpendicular to the motor shaft and in a horizontal direction.
The motor includes a support leg fixed to the base;
The axial parallel direction adjustment bolts include four bolts abutting on both ends of the support legs in the axial parallel direction,
The axial vertical adjustment bolts are made of four bolts abutting against both outer ends of the support legs in the axial vertical direction,
The motor centering is performed by
a first block portion on which the shaft vertical direction adjustment bolt and the fixing bolt are provided for the motor centering, a second block portion on which the shaft parallel direction adjustment bolt and the holding bolt are provided, and a third block portion are integrally formed;
the base includes a pedestal to which the support legs of the motor are fixed, and erected portions erected on both sides in a direction perpendicular to the axis,
the block body is fixed to the base by sandwiching the erected portion between the fixing bolt provided on the first block portion and the third block portion,
In the motor centering method for a hydraulic elevator power unit, the second block portion is fixed to the base by sandwiching the base between the holding bolt and the third block portion,
a first step of mounting the motor centering member on the base ;
a second step of measuring the misalignment of the motor and the pump;
a third step of adjusting a position of the motor by pushing the motor in a direction parallel to the axis using the axis parallel direction adjustment bolt, and adjusting a position of the motor by pushing the motor in a direction perpendicular to the axis and in a horizontal direction using the axis vertical direction adjustment bolt;
Equipped with.

The present invention provides a power unit and motor centering method for hydraulic elevators that can adjust the parallelism of the motor and pump, horizontal centering misalignment (eccentricity), and gaps between couplings in a short time without the need to rearrange parts or change the mounting position in the centering jig.

Problems, configurations, and advantages other than those described above will become clear from the description of the embodiments below.

FIG. 1 is a perspective view showing one embodiment of a motor centering mechanism for a hydraulic elevator power unit according to the present invention. FIG. 2 is a diagram showing the state of the first step (installing the motor centering member on the base) in one embodiment of the motor centering method for a hydraulic elevator power unit according to the present invention. FIG. 11 is a diagram showing the state of the second step (measuring the parallelism between couplings) in one embodiment of the motor centering method for a hydraulic elevator power unit according to the present invention. FIG. 11 is a diagram showing the state of the second step (measuring the eccentricity between couplings) in one embodiment of the motor centering method for a hydraulic elevator power unit according to the present invention. FIG. 11 is a diagram showing the state of the second step (measuring the clearance between the couplings) in one embodiment of the method for centering a motor of a power unit for a hydraulic elevator according to the present invention. FIG. 11 is a diagram showing the state of the second step (measuring the height between the couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. FIG. 11 is a diagram showing the state of the third step (adjusting the parallelism of couplings) in one embodiment of the method for centering a motor of a power unit for a hydraulic elevator according to the present invention. FIG. 11 is a diagram showing the state of the third step (adjusting the eccentricity between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. FIG. 11 is a diagram showing the state of the third step (adjusting the gap between the couplings) in one embodiment of the method for centering a motor of a power unit for a hydraulic elevator according to the present invention.

Below, we will explain the motor centering tool (motor centering jig) and motor centering method for a hydraulic elevator power unit according to an embodiment of the present invention, with reference to the drawings. Note that in each figure, the same components are designated by the same reference numerals, and duplicate explanations will be omitted.

Figure 1 is a perspective view showing one embodiment of a motor centering lever for a hydraulic elevator power unit according to the present invention. In Figure 1, the motor centering levers 1c and 1d arranged behind the motor 50 are shown as seen through the motor 50.

Hereinafter, the direction along the rotation axis 50x of the motor 50 (the direction parallel to the rotation axis) will be referred to as the axis-parallel direction, and the direction perpendicular to the rotation axis and parallel to the horizontal direction will be referred to as the axis-perpendicular direction. The axis-perpendicular direction coincides with the width direction W of the base 70.

As shown in FIG. 1, the motor centering device 1a according to this embodiment is composed of a block body 2a, fixing bolts 3a and 3b for fixing the block body 2a to the base 70, a pressing bolt 4a for adjusting and fixing the position of the block body 2a in the axial parallel direction, an axial parallel pressing bolt 5a for pushing the motor 50 in the axial parallel direction, and an axial perpendicular pressing bolt 6a for pushing the motor 50 in the axial perpendicular direction.

Similarly, the motor centering member 1b is composed of a block body 2b, fixing bolts 3c and 3d for fixing the block body 2b to the base 70, a pressing bolt 4b for adjusting and fixing the position of the block body 2b in the axial parallel direction, an axial parallel pressing bolt 5b for pushing the motor 50 in the axial parallel direction, and an axial perpendicular pressing bolt 6b for pushing the motor 50 in the axial perpendicular direction.

Similarly, the motor centering member 1c is composed of a block body 2c, fixing bolts 3e and 3f for fixing the block body 2c to the base 70, a pressing bolt 4c for adjusting and fixing the position of the block body 2c in the axial parallel direction, an axial parallel pressing bolt 5c for pushing the motor 50 in the axial parallel direction, and an axial perpendicular pressing bolt 6c for pushing the motor 50 in the axial perpendicular direction.

Similarly, the motor centering member 1d is composed of a block body 2d, fixing bolts 3g and 3h for fixing the block body 2d to the base 70, a pressing bolt 4d for positioning and fixing the block body 2d in the axial parallel direction, an axial parallel pressing bolt 5d for pushing the motor 50 in the axial parallel direction, and an axial perpendicular pressing bolt 6d for pushing the motor 50 in the axial perpendicular direction.

Motor centering members 1a, 1b, 1c, and 1d are installed at the four corners of motor 50, and their installation positions can be freely changed depending on the size of the motor. Specifically, when the rotating shaft 50x and motor centering members 1a, 1b, 1c, and 1d are projected onto a horizontal imaginary plane, motor centering members 1a and 1c are positioned opposite each other across the rotating shaft 50x, and motor centering members 1b and 1d are positioned opposite each other across the rotating shaft 50x.

The base 70 is provided with support parts 70a and 70b to which the motor 50 is fixed, and the motor 50 is provided with support legs 50a and 50b fixed to the pedestals (support parts) 70a and 70b of the base 70. In this embodiment, the pedestals 70a and 70b have a longitudinal direction perpendicular to the axis. The two pedestals 70a and 70b are arranged spaced apart in a direction parallel to the axis. In Figures 1 and 2, the support legs 50a and 50b provided on the motor centering sides 1a and 1c are shown by dashed lines. When projected onto the aforementioned imaginary plane, the motor 50 has two support legs 50a and 50b provided at positions facing each other across the rotation axis 50x.

The base 70 has a bolt insertion hole 70c through which a bolt (not shown) is inserted, the support legs 50a and 50b have bolt insertion holes 50c through which a bolt that passes through the bolt insertion hole 70c is inserted, and the motor 50 is centered and adjusted using the motor centering devices 1a, 1b, 1c, and 1d, and then fastened to the base 70 by a bolt that passes through the bolt insertion hole 70c and the bolt insertion hole 50c.

The block bodies 2a, 2b, 2c, and 2d of the motor centering members 1a, 1b, 1c, and 1d are fixed to the erected portions 70c erected on both sides (sides) of the flat portion 70p of the base 70 in the axially perpendicular direction by fixing bolts 3a, 3b, 3c, 3d, 3e, 3f, 3g, and 3h.

The hydraulic elevator power unit of this embodiment is a hydraulic elevator power unit that adjusts the mutual center of the motor 50 and the pump 60 of the hydraulic elevator power unit,
Motor centering members 1a, 1b, 1c, and 1d are attached to a base 70 that fixes the motor 50 to the four corners of the motor 50;
axial parallel direction adjustment bolts 5a, 5b, 5c, and 5d are provided on the motor centering bolts 1a, 1b, 1c, and 1d, and push the motor 50 in the axial parallel direction along the motor shaft 50x to adjust the position of the motor 50;
axial vertical adjustment bolts 6a, 6b, 6c, and 6d are provided on the motor centering bolts 1a, 1b, 1c, and 1d, and are used to push the motor 50 in an axial vertical direction perpendicular to the motor shaft 50x and in a horizontal direction to adjust the position of the motor 50;
Equipped with.

Next, with reference to Figures 2 to 9, we will explain how to adjust the relative alignment between the motor 50 and the pump 60 using the motor alignment devices 1a, 1b, 1c, and 1d described above.

Figure 2 shows the first step (installing the motor centering device on the base) in one embodiment of the motor centering method for a hydraulic elevator power unit according to the present invention.

The method for adjusting the mutual centering of the motor 50 and pump 60 in this embodiment involves, for example, adjusting the mutual centering of the motor 50 and pump 60 installed on the base 70 of the hydraulic power unit installed in the elevator machine room during elevator renovation work.

As described in detail below, the motor centering method according to this embodiment includes a first step of fixing the motor centering devices 1a, 1b, 1c, and 1d to the base 70 in accordance with the position of the motor 50; a second step of measuring the relative centering between the motor 50 and the pump 60; a third step of simultaneously adjusting the levelness, eccentricity, and gap between the couplings of the motor 50 and the pump 60 using the motor centering devices 1a, 1b, 1c, and 1d; and a fourth step of inserting a liner or the like between the motor 50 and the base 70 to adjust the height of the couplings.

Motor centering members 1a, 1b, 1c, and 1d have the same structure, so only motor centering member 1a will be described. Block body 2a includes a first block portion 2aa on which fixing bolts 3a and 3b and axially perpendicular pressing bolt 6a are provided, a second block portion 2ab on which pressing bolt 4a and axially parallel pressing bolt 5a are provided, and a third block portion 2ac which sandwiches erected portion 70c together with fixing bolts 3a and 3b from both sides perpendicular to the axis and sandwiches base 70a together with pressing bolt 4a from both sides parallel to the axis, and first block portion 2aa, second block portion 2ab, and third block portion 2ac are integrally configured.

The first block portion 2aa is provided with threaded portions (female threaded portions) into which the fixing bolts 3a, 3b and the axially perpendicular pressing bolt 6a are screwed. The second block portion 2ab is provided with threaded portions (female threaded portions) into which the pressing bolt 4a and the axially parallel pressing bolt 5a are screwed.

In the method of adjusting the mutual centering of the motor 50 and pump 60 in this embodiment, as a first step, as shown in FIG. 2, the motor centering bolt 1a is fixed to the base 70a portion that fixes the motor 50 in the axial direction by clamping the base 70a portion with the clamping bolt 4a and the third block portion 2ac of the block body 2a, and in the axial direction perpendicular to the axis, the vertical portion (rising portion) 70c on the side of the base 70 is fixed to the vertical portion 70c by clamping the vertical portion 70c with the fixing bolts 3a, 3b and the block body 2a.

In the same way, the motor centering member 1b is fixed to the base 70b portion in the axial direction by the clamping bolt 4b and the block body 2b, and is fixed to the erected portion 70c in the axial direction by the fixing bolts 3c, 3d and the block body 2b.

In the same manner, the motor centering lever 1c is fixed to the base 70a portion in the axial direction by the clamping bolt 4c and the block body 2c, and is fixed to the erected portion 70c in the axial direction by the fixing bolts 3e, 3f and the block body 2c.

In the same manner, the motor centering member 1d is fixed to the base 70b portion in the axial direction by the clamping bolt 4d and the block body 2d, and is fixed to the erected portion 70c in the axial direction by the fixing bolts 3g, 3h and the block body 2d.

Note that the motor centering members 1a, 1b, 1c, and 1d may be fixed to the base 70 in any order, not limited to the above order. This completes the first step.

The hydraulic elevator power unit of this embodiment is as follows:
The locking device includes a block body 2a integrally formed with a first block portion 2aa on which axis-perpendicular adjustment bolts 6a, 6b, 6c, 6d and fixing bolts 3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h are provided, a second block portion 2ab on which axis-parallel adjustment bolts 5a, 5b, 5c, 5d and pressing bolts 4a, 4b, 4c, 4d are provided, and a third block portion 2ac.
The base 70 includes pedestals 70a, 70b to which the support legs 50a, 50b of the motor 50 are fixed, and erected portions 70c erected on both sides in a direction perpendicular to the axis of the base 70.
The block body 2a is fixed to the base 70 by clamping the erected portion 70c between the fixing bolts 3a, 3b, 3c, 3d, 3e, 3f, 3g, and 3h provided on the first block portion 2aa and the third block portion 2ac.
The second block portion 2ab is fixed to the base 70 by sandwiching the pedestals 70a, 70b between the holding bolts 4a, 4b, 4c, 4d and the third block portion 2ac.

In this embodiment, the pedestals 70a, 70b of the base 70 are composed of two pedestals 70a, 70b spaced apart in the axial direction. The first block portion 2aa is disposed outside the base 70 with respect to the standing portion 70c. The second block portion 2ab is disposed inside the base 70 with respect to the standing portion 70c, and is disposed outside the two pedestals 70a, 70b in the axial direction. The third block portion 2ac is disposed inside the base 70 with respect to the standing portion 70c, and is disposed inside the two pedestals 70a, 70b.

The heads of the axially perpendicular adjustment bolts 6a, 6b, 6c, and 6d are positioned on the outside of the base 70 relative to the erected portion 70c, and the threaded portions are inserted from the outside to the inside of the base 70. The heads of the axially parallel adjustment bolts 5a, 5b, 5c, and 5d are positioned on the outside of the two pedestals 70a and 70b, and the threaded portions are assembled to the heads on the side facing from the outside to the inside of the two pedestals 70a and 70b.

This makes it easier to perform centering adjustments at motor centering positions 1a, 1b, 1c, and 1d.

Next, moving on to the second step, as shown in Figures 3 to 6, check for misalignment between the motor 50 and pump 60 (parallelism and eccentricity between couplings 80a, 80b) (Figures 3 and 4), the gap between couplings 80a, 80b (Figure 5), and misalignment in the height direction (Figure 6).

Figure 3 is a diagram showing the state of the second step (measuring the parallelism between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. Figure 4 is a diagram showing the state of the second step (measuring the eccentricity between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. Figure 5 is a diagram showing the state of the second step (measuring the gap between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. Figure 6 is a diagram showing the state of the second step (measuring the height between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention.

At this time, the misalignment can be measured using a dial gauge or gap gauge (not shown). This completes the second step.

The misalignment of the motor 50 and pump 60 in the height direction relative to each other (Figure 6) can also be included in the eccentricity, but in this embodiment, the misalignment in the horizontal direction is considered to be the eccentricity, and the misalignment in the height direction is distinguished from the eccentricity.

Next, moving on to the third step, as shown in Figures 7 to 9, the relative alignment of the motor 50 and the pump 60 is adjusted using any two of the four motor alignment bolts 1a, 1b, 1c, 1d, namely, the axial parallel pressing bolts 5a, 5b, 5c, 5d or the axial vertical pressing bolts 6a, 6b, 6c, 6d. The axial parallel pressing bolts 5a, 5b, 5c, 5d are sometimes called axial parallel adjustment bolts because they press the motor 50 in a direction along the motor shaft 50x to adjust the position of the motor 50. The axial vertical pressing bolts 6a, 6b, 6c, 6d are sometimes called axial vertical adjustment bolts because they press the motor 50 in a direction perpendicular to the motor shaft 50x and in the horizontal direction to adjust the position of the motor 50.

During centering adjustment, the axially parallel pressing bolts 5a, 5b, 5c, and 5d abut against both ends of the support legs 50a and 50b in the axially parallel direction and press the support legs 50a and 50b, thereby adjusting the centering of the motor 50 and the pump 60. During centering adjustment, the axially perpendicular pressing bolts 6a, 6b, 6c, and 6d abut against both outer ends of the support legs 50a and 50b in the axially perpendicular direction and press the support legs 50a and 50b, thereby adjusting the centering of the motor 50 and the pump 60.

That is, in this embodiment,
The motor 50 includes support legs 50a and 50b fixed to a base 70.
The axial parallel direction adjustment bolts 5a, 5b, 5c, and 5d are made up of four bolts that abut against both ends of the support legs 50a and 50b in the axial parallel direction.
The axially vertical adjustment bolts 6a, 6b, 6c, and 6d are made up of four bolts that abut against both outer ends of the support legs 50a and 50b in the axially vertical direction.

Figure 7 is a diagram showing the state of the third step (adjusting the parallelism between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. Figure 8 is a diagram showing the state of the third step (adjusting the eccentricity between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention. Figure 9 is a diagram showing the state of the third step (adjusting the gap between couplings) in one embodiment of the motor centering method for a power unit for a hydraulic elevator according to the present invention.

For example, as shown in FIG. 7, when rotating around the motor 50 to adjust the parallelism of the couplings 80a and 80b, if the motor is rotated clockwise, the axially perpendicular flat bolts 6b and 6c are tightened with a spanner or wrench, and if the motor is rotated counterclockwise, the axially perpendicular flat bolts 6a and 6d are tightened with a spanner or wrench, and the motor 50 is rotated to adjust the misalignment between the motor 50 and the pump 60. In this case, since the motor centering members 1a, 1b, 1c, and 1d are located at the corners of a square, it is advisable to adjust the misalignment using one of the motor centering members 1a and 1d located at the diagonal or the other motor centering member 1b and 1c.

Similarly, for example, as shown in FIG. 8, when the motor 50 is moved vertically to the motor shaft 50x to adjust the eccentricity of the couplings 80a, 80b, the axially vertical pressing bolts 6c, 6d or the axially vertical flat pressing bolts 6a, 6b are tightened with a spanner or wrench to adjust the misalignment between the motor 50 and the pump 60 via the axially vertical pressing bolts 6c, 6d or the axially vertical pressing bolts 6a, 6b.

Similarly, for example, as shown in FIG. 9, when moving the motor 50 horizontally relative to the motor shaft to adjust the gap between the couplings 80a and 80b, tighten the axial parallel pressing bolts 5a, 5c or the axial parallel pressing bolts 5b, 5d with a spanner or wrench, and adjust the misalignment between the motor 50 and the pump 60 via the axial parallel pressing bolts 5a, 5c or the axial parallel pressing bolts 5b, 5d.

When adjusting the centering, it is advisable to temporarily fix the motor 50 and base 70 with a bolt (not shown) that passes through the bolt insertion hole 70c and the bolt insertion hole 50c to prevent a large misalignment between the motor 50 and the pump 60, and then adjust the centering misalignment between the motor 50 and the pump 60. This completes the third step.

The motor centering method of the present embodiment is a method for centering a motor of a power unit for a hydraulic elevator, which adjusts the mutual centering of the motor 50 and the pump 60 of the power unit for a hydraulic elevator,
A first step of installing motor centering members 1a, 1b, 1c, and 1d on a base 70 that fixes the motor 50 to four corners of the motor 50;
a second step of measuring the misalignment of the motor 50 and the pump 60 relative to each other;
a third step of adjusting the position of the motor 50 by pushing the motor 50 in an axial parallel direction along the motor shaft 50x using the axial parallel direction adjustment bolts 5a, 5b, 5c, 5d provided on the motor centering positions 1a, 1b, 1c, 1d, and also adjusting the position of the motor 50 by pushing the motor 50 in an axial vertical direction perpendicular to the motor shaft 50x and in a horizontal direction using the axial vertical direction adjustment bolts 6a, 6b, 6c, 6d provided on the motor centering positions 1a, 1b, 1c, 1d;
Equipped with.

In the motor centering method of this embodiment,
Using the motor centering devices 1a, 1b, 1c, and 1d, the parallelism and eccentricity of the couplings 80a, 80b between the motor 50 and the pump 60, and the gap between the couplings 80a, 80b are simultaneously adjusted.

In this embodiment, when the third step is completed, the axially parallel pressing bolts 5a, 5b, 5c, 5d and the axially perpendicular pressing bolts 6a, 6b, 6c, 6d are all in contact with the support legs 50a, 50b of the motor 50, and the positioning of the support legs 50a, 50b of the motor 50 in the horizontal direction, i.e., the positioning of the motor 50, is complete.

Next, proceed to the fourth step, where a liner or the like is inserted between the motor 50 and the base 70 to adjust the height difference between the couplings 80a and 80b.

In addition, for screw holes fixing the motor 50 and base 70 other than between the motor 50 and base 70 where the liner etc. is inserted, the motor 50 and base 70 are fixed with bolts (not shown) to prevent the fixing positions of the motor 50 and base 70 from shifting significantly, and then the liner etc. is inserted. This completes the fourth step.

When all centering adjustments have been completed, the motor 50 is fastened to the base 70 by a bolt that passes through the bolt insertion hole 70c and the bolt insertion hole 50c.

According to the motor centering device and motor centering method for a hydraulic elevator power unit of this embodiment, the parallel and eccentric couplings 80a, 80b of the motor 50 and pump 60 can be adjusted simultaneously and the gap between the couplings can be adjusted using the axial parallel pressing bolts 5a, 5b, 5c, 5d and the axial perpendicular pressing bolts 6a, 6b, 6c, 6d without adjusting the mutual centering between the motor 50 and pump 60 by hitting them with a hammer, and the mutual centering between the motor 50 and pump 60 can be adjusted efficiently. This also means that the parallelism, eccentricity, and gap between the couplings can be adjusted without rearranging the parts in the centering jig or changing the mounting positions.

The present invention is not limited to the above-described embodiment, but includes various modified examples. For example, the above-described embodiment has been described in detail to explain the present invention in an easy-to-understand manner, and is not necessarily limited to having all of the configurations described. In addition, it is possible to add or replace some of the configurations of the embodiment with other configurations.

1a, 1b, 1c, 1d...motor centering member, 2a...block body, 2aa...first block part, 2ab...second block part, 2ac...third block part, 3a, 3b, 3c, 3d, 3e, 3f, 3g, 3h...fixing bolt, 4a, 4b, 4c, 4d...holding bolt, 5a, 5b, 5c, 5d...shaft parallel direction adjustment bolt, 6a, 6b, 6c, 6d...shaft perpendicular direction adjustment bolt, 50...motor, 50a, 50b...support leg, 50x...motor shaft, 60...pump, 70...base, 70a, 70b...pedestal, 70c...standing part, 80a, 80b...coupling.

Claims (4)

In a hydraulic elevator power unit, which adjusts the mutual center of the motor and pump of the hydraulic elevator power unit,
a motor centering shaft attached to a base that fixes the motor to four corners of the motor;
an axial parallel direction adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial parallel direction along the motor shaft;
and an axial vertical adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial vertical direction perpendicular to the motor shaft and in a horizontal direction .
The motor includes a support leg fixed to the base;
The axial parallel direction adjustment bolts include four bolts abutting on both ends of the support legs in the axial parallel direction,
The axial vertical adjustment bolts are made of four bolts abutting against both outer ends of the support legs in the axial vertical direction,
The motor centering is performed by
a first block portion on which the shaft vertical direction adjustment bolt and the fixing bolt are provided for the motor centering, a second block portion on which the shaft parallel direction adjustment bolt and the holding bolt are provided, and a third block portion are integrally formed;
the base includes a pedestal to which the support legs of the motor are fixed, and erected portions erected on both sides in a direction perpendicular to the axis,
the block body is fixed to the base by sandwiching the erected portion between the fixing bolt provided on the first block portion and the third block portion,
A power unit for a hydraulic elevator, characterized in that the second block portion is fixed to the base by clamping the base between the pressure bolt and the third block portion . In claim 1 ,
The pedestal of the base includes two pedestals spaced apart from each other in an axial direction,
the first block portion is disposed outside the base with respect to the standing portion,
the second block portion is disposed on the inside of the base with respect to the upright portion and on the outside of the two pedestals,
the third block portion is disposed on the inside of the base with respect to the standing portion, and is disposed on the inside of the two pedestals,
The head of the axial vertical adjustment bolt is disposed on the outside of the base with respect to the upright portion, and the threaded portion is inserted from the outside of the base toward the inside thereof,
a head of the axial parallel direction adjustment bolt being arranged on the outside relative to the two pedestals, and a threaded portion being assembled on the side of the head from the outside to the inside of the two pedestals. A hydraulic elevator power unit that adjusts the mutual center of a motor and a pump of the hydraulic elevator power unit ,
a motor centering shaft attached to a base that fixes the motor to four corners of the motor;
an axial parallel direction adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial parallel direction along the motor shaft;
and an axial vertical adjustment bolt provided at the center of the motor for adjusting the position of the motor by pushing the motor in an axial vertical direction perpendicular to the motor shaft and in a horizontal direction.
The motor includes a support leg fixed to the base;
The axial parallel direction adjustment bolts include four bolts abutting on both ends of the support legs in the axial parallel direction,
The axial vertical adjustment bolts are made of four bolts abutting against both outer ends of the support legs in the axial vertical direction,
The motor centering is performed by
a first block portion on which the shaft vertical direction adjustment bolt and the fixing bolt are provided for the motor centering, a second block portion on which the shaft parallel direction adjustment bolt and the holding bolt are provided, and a third block portion are integrally formed;
the base includes a pedestal to which the support legs of the motor are fixed, and erected portions erected on both sides in a direction perpendicular to the axis,
the block body is fixed to the base by sandwiching the erected portion between the fixing bolt provided on the first block portion and the third block portion,
In the motor centering method for a hydraulic elevator power unit, the second block portion is fixed to the base by sandwiching the base between the holding bolt and the third block portion,
a first step of mounting the motor centering member on the base ;
a second step of measuring the misalignment of the motor and the pump;
a third step of adjusting a position of the motor by pushing the motor in a direction parallel to the axis using the axis parallel direction adjustment bolt, and adjusting a position of the motor by pushing the motor in a direction perpendicular to the axis and in a horizontal direction using the axis vertical direction adjustment bolt;
A method for centering a motor of a power unit for a hydraulic elevator, comprising: In claim 3 ,
A method for centering a motor of a power unit for a hydraulic elevator, characterized in that the motor centering tool is used to simultaneously adjust the parallelism, eccentricity, and gap between the couplings of the motor and the pump.

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