JP6345374B1 - Elevator equipment - Google Patents

Abstract

In the elevator apparatus, a hoisting machine having a driving sheave on which a load from a car and a counterweight acts is provided with an anti-vibration rubber 21 that is a first anti-vibration member provided on the lower surface of the upper blade, and an upper blade. Are fixed to the hoisting machine base by through bolts through a vibration isolating rubber 22 which is a second vibration isolating member provided on the lower surface of the lower blade provided with a space in the vertical direction.

Description

  The present invention relates to an elevator apparatus having elevator equipment such as a hoisting machine.

  In a rope type elevator apparatus, an elevator device such as a hoisting machine is vibrated by its own weight, a load received from a car and a counterweight, an earthquake, or the like. It is necessary to suppress such vibration as much as possible.

  Therefore, in the apparatus described in Patent Document 1, elastic bodies are arranged at four locations on the top, bottom, left, and right of the hoisting machine, and a load is applied to the hoisting machine through four frames. In the apparatus described in Patent Document 2, a vibration isolating rubber is disposed directly under a load acting on the hoisting machine.

WO2008 / 041266 Publication WO2016 / 024347

However, in the apparatus described in Patent Document 1, there are limitations on the location and fixing method for fixing the hoisting machine, and the configuration itself becomes large. In the apparatus described in Patent Document 2, when the applied load increases, it is necessary to increase the vibration-proof rubber in proportion to the load.
In any apparatus, it is difficult to arrange the vibration-proof member in a space-saving manner with respect to the hoisting machine.

  In order to solve the above-described problems, in the elevator apparatus of the present invention, an elevator device having a sheave on which a load from a car and a counterweight acts, and an installation portion and an installation portion where the elevator device is provided A device base having a fixing portion provided to be opposed to each other with an interval in the vertical direction, a first vibration isolation member provided on one of the installation portion and the fixing portion, and a second anti-vibration member provided on the other A vibration member, and a through bolt that penetrates the first vibration isolation member and the second vibration isolation member, the installation portion and the fixing portion each have an upper surface and a lower surface, and the first vibration isolation member of the installation portion When provided on the lower surface, the second vibration isolation member is provided on the lower surface of the fixed portion, and when the first vibration isolation member is provided on the upper surface of the fixed portion, the second vibration isolation member is provided on the installation portion. The elevator apparatus is provided with a first vibration isolating member and a second anti-vibration member. Through the member, and is fixed to the device base by a through bolt.

  In the elevator apparatus according to the present invention, the first vibration isolation member and the second vibration isolation member are arranged one above the other through the through bolts. Thereby, the vibration isolating member can be arranged in a space saving plane.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the elevator apparatus by Embodiment 1 of this invention. It is a front view which shows the structure of the winding machine periphery by Embodiment 1 of this invention. It is a fragmentary sectional view which follows III-III of FIG. It is a block diagram which shows the elevator apparatus by Embodiment 2 of this invention. It is a front view which shows the structure of the winding machine periphery by Embodiment 2 of this invention. It is a fragmentary sectional view which follows VI-VI of FIG. It is a front view which shows the structure of the cage | basket | car side return wheel periphery by Embodiment 3 of this invention. It is a fragmentary sectional view which follows VIII-VIII of FIG. It is a front view which shows the structure of the car suspension vehicle periphery by Embodiment 4 of this invention.

  Embodiments of an elevator apparatus according to the present invention will be described below with reference to the drawings. In addition, in each figure, the same or an equivalent part is shown with the same code | symbol, and the overlapping description is abbreviate | omitted.

Embodiment 1 FIG.
1 is a block diagram showing an elevator apparatus according to Embodiment 1 of the present invention.

  A car 2 and a counterweight 3 are disposed in the hoistway 1 so as to be able to move up and down. At the bottom of the hoistway 1, a hoisting machine 4 having a drive sheave 5 is installed on a bulkhead 7 via a hoisting machine base 6. The driving sheave 5 constitutes a sheave, the hoisting machine 4 constitutes an elevator equipment, and the hoisting machine base 6 constitutes an equipment base.

  In the upper part in the hoistway 1, a car-side return wheel 9, a counterweight-side return wheel 10, a first leashing device 11, and a second leashing device 12 are provided. A car suspension wheel 13 is provided at the top of the car 2. A counterweight suspension wheel 14 is provided on the upper portion of the counterweight 3.

One end of the rope 8 is fixed by the first rope stopping device 11, and the other end of the rope 8 is fixed by the second rope stopping device 12. The rope 8 is connected to the car suspension wheel 13, the car return wheel 9, the driving sheave 5 of the hoisting machine 4, the counterweight counterwheel 10, and the counterweight suspension wheel 14 from the first leashing device 11. It is wound around in order and reaches the second rope stopping device 12.
The car 2 and the counterweight 3 are moved up and down in the hoistway 1 by the movement of the rope 8 by the rotation of the driving sheave 5 of the hoist 4.

  FIG. 2 is a front view showing a configuration around the hoisting machine of FIG.

  An anti-vibration rubber 51 is provided on the hoisting machine base 6 on the side where the driving sheave 5 is located. Further, a vibration isolating rubber 56 is provided on the side where the driving sheave 5 is not present (see FIG. 3). One anti-vibration rubber 51 is provided on each of the left and right sides of the central axis C of the drive sheave 5. Anti-vibration rubber 56 is provided behind each anti-vibration rubber 51. That is, on the hoisting machine base 6, there is a set of anti-vibration rubber 51 and a set of anti-vibration rubbers 56, and the hoisting machine 4 is installed on the anti-vibration rubbers 51 and 56. .

  Immediately below the anti-vibration rubber 51, an anti-vibration rubber 21 as a first anti-vibration member and an anti-vibration rubber 22 as a second anti-vibration member are provided. Anti-vibration rubbers 21 and 22 are provided on the left and right sides of the central axis C of the drive sheave 5 respectively.

  A rope 8 is wound around the driving sheave 5 of the hoist 4 and extends upward. A brake 4 b is installed on the upper part of the hoisting machine 4.

  On the counterweight 3 side of the hoisting machine base 6, a guide rail 16a for counterweight is installed. The hoisting machine base 6 is fastened to the guide rail 16a via a steady rest 15 attached to the side portion. A guide rail 16 b for the car 2 is installed on the side of the driving sheave 5 of the hoisting machine base 6.

  FIG. 3 is a partial cross-sectional view showing a configuration around the hoisting machine 4 along III-III in FIG. 2. In FIG. 3, the side where the driving sheave 5 of the hoist 4 is present is defined as the front direction HF, and the side where the sheave 5 is not present is defined as the rear direction HB.

  The hoisting machine base 6 has a substantially flat hoisting machine base upper plate 61 and a hoisting machine base supporting plate 62 having a substantially C-shaped cross section. The hoisting machine base upper plate 61 and the hoisting machine base support plate 62 are in contact with each other in the vertical direction. The hoisting machine base support plate 62 has an upper blade 6a and a lower blade 6b. The upper blade 6a of the hoisting machine base upper plate 61 and the hoisting machine base supporting plate 62 constitutes an installation part of the equipment base. The lower blade 6b of the hoisting machine base support plate 62 is provided to face the upper blade 6a with a space in the vertical direction, and constitutes a fixed portion of the equipment table.

  On the upper surface 61 u of the hoisting machine base upper plate 61, the hoisting machine 4 is installed via anti-vibration rubbers 51 and 56. The anti-vibration rubber 21 is provided on the lower surface 61d of the upper blade 6a, and the anti-vibration rubber 22 is provided on the lower surface 62d of the lower blade 6b. Here, the anti-vibration rubber 51 constitutes a third anti-vibration member.

  A through bolt 20 is provided in the mounting flange portion 4 f on the front direction HF side of the hoisting machine 4. The through bolt 20 passes through the mounting flange portion 4f of the hoisting machine 4, the anti-vibration rubber 51, the hoisting machine base upper plate 61, the upper blade 6a, the anti-vibration rubber 21, the lower blade 6b, and the anti-vibration rubber 22. Yes. The through bolt 20 uses the washer 17 and the double nut 18 to fix the vibration isolating rubber 21 to the lower surface 61d of the upper blade 6a. Further, the through bolt 20 uses the washer 17 and the double nut 18 to fix the vibration isolating rubber 22 to the lower surface 62d of the lower blade 6b. That is, the hoisting machine 4 is fixed to the hoisting machine base 6 by the through bolts 20 through the antivibration rubber 21 and the antivibration rubber 22.

  On the rear direction HB side of the hoisting machine 4, anti-vibration rubber 56 having bolts on the upper and lower sides is provided. The bolts on the top of the anti-vibration rubber 56 are fixed to the mounting flange portion 4f with nuts. Further, the bolts below the vibration isolating rubber 56 are fixed to the hoisting machine base upper plate 61 with nuts.

  Below, the effect | action of the elevator apparatus by Embodiment 1 is demonstrated using FIG.

  The hoisting machine 4 is supported by four anti-vibration rubbers 51 and 56 immediately below the hoisting machine 4. The own weight of the hoist 4 acts as a compressive load on the anti-vibration rubbers 51 and 56.

  On the other hand, the load acting on the driving sheave 5 from the car 2 and the counterweight 3 acts upward as indicated by the arrow P11 in FIGS. This load acts on the hoist 4 and acts as a tensile load on the through bolt 20. The tensile load applied to the through bolt 20 is dispersed in the anti-vibration rubbers 21 and 22 and acts as a compression load for each. The swing of the hoisting machine base 6 itself is suppressed by the guide rail 16 a via the steady rest 15.

As described above, in the elevator apparatus according to the first embodiment, the anti-vibration rubbers 21 and 22 that support the load from the car 2 and the counterweight 3 are arranged up and down, so The area can be reduced.
In other words, the first vibration isolation member and the second vibration isolation member are arranged above and below via the through bolts. Thereby, the vibration isolating member can be arranged in a space saving plane.

  Further, when the anti-vibration rubbers 21 and 22 are arranged above and below and the loads from the car 2 and the counterweight 3 are distributed and acted on the anti-vibration rubbers 21 and 22, the anti-vibration rubbers 21 and 22 act using one anti-vibration rubber. Compared with the case of making it, the volume of a vibration-proof rubber can be made small. Therefore, the vertical space can be reduced. As a result, the maintainability of the hoist 4 can be improved.

  Furthermore, it is no longer necessary to assemble a conventional four-sided frame, the size and structure of the hoisting machine base 6 itself can be simplified, and it can be made smaller and lighter. Thus, the production cost of the hoisting machine base 6 can be reduced and the installation can be improved. Can be achieved.

Next, a case where an earthquake occurs will be described. When an earthquake occurs, a horizontal load acts near the center of gravity of the hoist 4.
First, the case where a horizontal load in a direction parallel to the central axis C of the drive sheave 5 acts on the hoist 4 will be described with reference to FIG.

  First, when a horizontal load is applied to the hoisting machine 4 on the side where the driving sheave 5 of the hoisting machine 4 is present, that is, in the forward direction HF, the hoisting machine 4 is compressed to the anti-vibration rubber 51 disposed immediately below the hoisting machine 4. A load acts and can suppress horizontal shaking.

  Next, when a horizontal load acts on the hoisting machine 4 in the backward direction HB, the load acts on the anti-vibration rubber 56 as a compression load. At the same time, the through-bolt 20 is pulled up by the load, and a compression load acts on the anti-vibration rubbers 21 and 22 to suppress horizontal shaking.

  Further, since the through bolt 20 passes through the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62, the position P1 of the upper blade 6a and the position of the lower blade 6b of the hoisting machine base support plate 62 Contact P2 diagonally. At those positions P1 and P2, the members constituting the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62 serve as stoppers that receive shaking due to the earthquake, and the top 4a of the hoisting machine 4 swings. Can be suppressed.

  Next, a case where a horizontal load in a direction perpendicular to the central axis C of the drive sheave 5 acts on the hoist 4 will be described with reference to FIG. In FIG. 2, with respect to the hoisting machine 4, the direction where the guide rail 16a is present is the right direction HR, and the direction where the guide rail 16a is not is the left direction HL.

  First, when a horizontal load acts on the hoist 4 in the left direction HL, the load acts as a compressive load on the anti-vibration rubber 51 on the left direction HL side and the anti-vibration rubber 56 behind it. At the same time, the load acts as a compressive load on the anti-vibration rubbers 21 and 22 on the right direction HR side through the through bolts 20 on the right direction HR side, thereby suppressing horizontal shaking. .

  Further, since the through bolt 20 on the right direction HR side passes through the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62, the upper blade 6a and the lower blade of the hoisting machine base support plate 62 6b is contacted diagonally. Therefore, the members constituting the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62 serve as a stopper that receives a shake against an earthquake, and suppresses the shake of the top 4a of the hoisting machine 4. it can.

  Next, when a horizontal load acts on the hoisting machine 4 in the right direction HR, the load acts as a compressive load on the anti-vibration rubber 51 on the right direction HR side and the anti-vibration rubber 56 behind it. At the same time, the load acts as a compressive load on the anti-vibration rubbers 21 and 22 on the left direction HL side through the through bolt 20 on the left direction HL side, thereby suppressing horizontal shaking. .

  Further, the through bolt 20 on the left direction HL side comes in diagonal contact with the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62. Therefore, the members constituting the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62 serve as stoppers that are subject to shaking, and the vibration of the top 4a of the hoisting machine 4 can be suppressed.

  As described above, in the elevator apparatus according to the first embodiment, the first anti-vibration rubber 21 and the anti-vibration rubber 22 as the second anti-vibration member are arranged up and down at the same time. Since the anti-vibration rubber 51 as the third anti-vibration member is provided on the upper surface 61u of the hoisting machine upper plate 61, the horizontal shaking of the hoisting machine 4 caused by an earthquake or the like can be suppressed.

  Further, since the through bolt 20 passes through the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62, the upper blade 6a and the lower blade 6b are diagonally formed with respect to the hoisting machine base support plate 62. Contact. Therefore, the members constituting the upper blade 6a and the lower blade 6b of the hoisting machine base support plate 62 serve as a stopper that receives shaking against an earthquake, and mechanically stops the vibration of the top 4a of the hoisting machine 4. be able to. As a result, the elevator apparatus can be safely operated even if an earthquake occurs.

Embodiment 2. FIG.
Next, an elevator apparatus according to Embodiment 2 will be described. In the second embodiment, an example is shown in which the hoisting machine at the bottom of the hoistway in the first embodiment is installed at the top of the hoistway. The direction of the load received by the driving sheave of the hoisting machine from the car and the counterweight is upside down.

  4 is a block diagram showing an elevator apparatus according to Embodiment 2 of the present invention.

  A hoisting machine base 106 supported by guide rails 16a and 16b is installed at the uppermost part in the hoistway 1. The hoisting machine 4 having the drive sheave 5 is installed on the hoisting machine base 106. A counterweight suspension wheel 14 is provided on the counterweight 3. The driving sheave 5 constitutes a sheave, the hoisting machine 4 constitutes an elevator equipment, and the hoisting machine base 106 constitutes an equipment base. The rope 8 is wound around the counterweight suspension wheel 14 and the driving sheave 5 in this order from a rope stopping device (not shown) and reaches a car (not shown).

  FIG. 5 is a front view showing a configuration around the hoisting machine of FIG. In the second embodiment, a through hole for placing the hoisting machine and the hoisting machine base at the uppermost part of the hoistway, that is, a lifting point is provided at the upper end of the through bolt. Further, the shape of the hoisting machine base is different.

  An anti-vibration rubber 22 is provided on the hoisting machine base 106 on the side where the driving sheave 5 is located. Further, a vibration isolating rubber 57 is provided on the side where the driving sheave 5 is not present (see FIG. 6). One anti-vibration rubber 22 is provided on each of the left and right sides of the central axis C of the drive sheave 5. Antivibration rubber 57 is provided behind each antivibration rubber 22. That is, on the hoisting machine base 106, there is a set of anti-vibration rubber 22 and a set of anti-vibration rubber 57. On the anti-vibration rubbers 22 and 57, the hoisting machine 4 is installed. .

  An anti-vibration rubber 21 is provided directly below the anti-vibration rubber 22. Further, an anti-vibration rubber 52 is provided immediately below the anti-vibration rubber 21. The anti-vibration rubbers 21 and 52 are respectively provided on the left and right sides of the central axis C of the drive sheave 5.

  6 is a partial cross-sectional view showing a configuration around the hoisting machine along VI-VI in FIG. 5. The side where the drive sheave 5 of the hoist 4 is present is defined as the front direction HF, and the side where the sheave 5 is not present is defined as the rear direction HB.

  The hoisting machine base 106 includes a substantially flat hoisting machine base upper plate 71, a hoisting machine base supporting plate 72 having a substantially C-shaped cross section, and a substantially flat hoisting machine base lower plate 73. The hoisting machine base upper plate 71 and the hoisting machine base support plate 72 are in contact with each other in the vertical direction. The hoisting machine base support plate 72 and the hoisting machine base lower plate 73 are in contact with each other in the vertical direction. The hoisting machine base upper plate 71 constitutes an installation part of the equipment base. The hoisting machine base lower plate 73 is provided to face the hoisting machine base upper plate 71 with an interval in the vertical direction, and constitutes a fixed part of the equipment base.

  On the upper surface 71 u of the hoisting machine upper plate 71, the hoisting machine 4 is installed via the anti-vibration rubbers 22 and 57. The anti-vibration rubber 22 constitutes a second anti-vibration member. An anti-vibration rubber 21 as a first anti-vibration member is disposed on the upper surface 73 u of the hoisting machine lower plate 73. An anti-vibration rubber 52 as a third anti-vibration member is disposed on the lower surface 73 d of the hoisting machine lower plate 73.

  On the rear direction HB side of the hoisting machine 4, anti-vibration rubber 57 having bolts on the upper and lower sides is provided. The bolts on the top of the vibration isolating rubber 57 are fixed to the mounting flange portion 4f with nuts. The bolts below the anti-vibration rubber 57 are fixed to the hoisting machine base upper plate 71 with nuts.

A through bolt 201 is provided on the mounting flange portion 4 f on the front direction HF side of the hoisting machine 4. The through bolt 201 penetrates the mounting flange portion 4f of the hoisting machine 4, the vibration isolating rubber 22, the hoisting machine base upper plate 71, the anti-vibration rubber 21, the hoisting machine base lower plate 73, and the anti-vibration rubber 52. Yes. The through bolt 201 uses the washer 17 and the double nut 18 to fix the vibration isolating rubber 21 to the upper surface 73 u of the hoisting machine lower plate 73. Further, the through bolt 201 uses the washer 17 and the double nut 18 to fix the anti-vibration rubber 52 to the lower surface 73 d of the hoisting machine base lower plate 73.
Further, the through bolt 201 is provided with a male screw, and the upper portion of the mounting flange portion 4 f of the hoisting machine 4 is fixed with a nut 211. Further, the through bolt 201 has a lower portion of the mounting flange portion 4 f of the hoisting machine 4 fixed by a nut 212.

  In order to install the hoisting machine and the hoisting machine stand at the uppermost part of the hoistway, it is necessary to provide lifting hoisting points for lifting the hoisting machine and the like in the hoisting machine.

  In the elevator apparatus according to the second embodiment, a through hole portion 29 that is a hole portion penetrating in the horizontal direction is provided at the top end of the through bolt 201 as a lifting point. By using this through-hole portion 29, it is not necessary to provide a dedicated lifting point for the hoist 4 itself. Further, the through hole 29 can be provided in a place lower than the top 4 a of the hoisting machine 4. Therefore, even if there is not enough space at the uppermost part of the hoistway, the hoisting machine 4 and the hoisting machine base 106 can be installed at the uppermost part of the hoistway by using this through-hole portion 29.

  Below, the effect | action of the elevator apparatus by Embodiment 2 is demonstrated using FIG.

  The hoisting machine 4 is supported by four anti-vibration rubbers 22 and 57 immediately below the hoisting machine 4. The own weight of the hoist 4 acts as a compressive load on the anti-vibration rubbers 22 and 57.

  On the other hand, the load acting on the driving sheave 5 from the car and the counterweight 3 acts downward as indicated by the arrow P12 in FIGS. This load acts on the hoisting machine 4 and is distributed to the anti-vibration rubber 22 and the anti-vibration rubber 21 via the through bolts 201 and acts as a compression load on each.

As described above, in the elevator apparatus according to the second embodiment, the vibration isolating rubbers 21 and 22 that support the load from the car and the counterweight 3 are arranged above and below, so that the area of the anti-vibration rubber as viewed in a plan view is obtained. Can be reduced.
In other words, the first vibration isolation member and the second vibration isolation member are arranged above and below via the through bolts. Thereby, the vibration isolating member can be arranged in a space saving plane.

Next, a case where an earthquake occurs will be described. When an earthquake occurs, a horizontal load acts near the center of gravity of the hoist 4.
First, the case where a horizontal load in a direction parallel to the central axis C of the driving sheave 5 acts on the hoist 4 will be described with reference to FIG.

  First, when a horizontal load is applied to the hoisting machine 4 in the forward direction HF, a compressive load is applied to the antivibration rubber 22 disposed immediately below the hoisting machine 4 and at the same time, the vibration isolating is performed via the through bolt 201. It acts as a compressive load on the rubber 21 and can suppress horizontal shaking.

  Next, when a horizontal load acts on the hoist 4 in the rearward direction HB, the load acts on the anti-vibration rubber 57 as a compression load. At the same time, the through-bolt 201 is pulled up by the load, a compressive load acts on the anti-vibration rubber 52, and horizontal shaking can be suppressed.

  Further, since the through bolt 201 penetrates the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73, it comes into contact with the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 diagonally. . Therefore, the members constituting the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 serve as a stopper that receives a shake against an earthquake, and suppresses the shake of the top 4 a of the hoisting machine 4. it can.

  Next, a case where a horizontal load in a direction perpendicular to the central axis C of the drive sheave 5 acts on the hoist 4 will be described with reference to FIG. In FIG. 5, with respect to the hoisting machine 4, the direction on the side where the guide rail 16b is installed is the left direction HL, and the opposite direction is the right direction HR.

  First, when a horizontal load acts on the hoist 4 in the left direction HL, the load acts as a compressive load on the anti-vibration rubber 22 on the left direction HL side and the anti-vibration rubber 57 behind it. At the same time, the through bolt 201 on the right direction HR side is pulled up by the load, and a compressive load acts on the anti-vibration rubber 52 on the right direction HR side, thereby suppressing horizontal shaking.

  Further, since the through bolt 201 on the right direction HR side passes through the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73, the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73. Contact diagonally. Therefore, the members constituting the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 serve as a stopper that receives a shake against an earthquake, and suppresses the shake of the top 4 a of the hoisting machine 4. it can.

  Next, when a horizontal load acts on the hoisting machine 4 in the right direction HR, the load acts as a compressive load on the anti-vibration rubber 22 on the right direction HR side and the anti-vibration rubber 57 behind it. At the same time, the horizontal vibration can be suppressed by the load acting as a compressive load on the anti-vibration rubber 52 on the left direction HL side through the through bolt 201 on the left direction HL side.

  Further, the through bolt 201 on the left direction HL side comes in diagonal contact with the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73. Therefore, the members constituting the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 serve as a stopper that receives the shaking, and the swing of the top portion 4a of the hoisting machine 4 can be suppressed.

  As described above, in the elevator apparatus according to the second embodiment, the first anti-vibration rubber 21 and the anti-vibration rubber 22 as the second anti-vibration member are arranged up and down at the same time. Since the anti-vibration rubber 52, which is the anti-vibration member 3, is provided on the lower surface 73d of the hoisting machine lower plate 73, the horizontal shaking of the hoisting machine 4 caused by an earthquake or the like can be suppressed.

  Further, since the through bolt 201 penetrates the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73, it comes into contact with the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 diagonally. . Therefore, the members constituting the hoisting machine base upper plate 71 and the hoisting machine base lower plate 73 serve as a stopper that receives a shake against an earthquake, and mechanically stops the vibration of the top part 4a of the hoisting machine 4. be able to. As a result, it is possible to drive safely even if an earthquake occurs.

Embodiment 3 FIG.
In the first and second embodiments, the case where the present invention is applied to a hoisting machine has been described. However, the present invention can also be applied to a top return wheel such as a car side return wheel and a counterweight side return wheel. Embodiment 3 shows a case where the present invention is applied to a car-side return wheel.

  FIG. 7 is a front view showing the configuration around the car side reverse wheel according to the third embodiment of the present invention, and FIG. 8 is a partial sectional view taken along line VIII-VIII in FIG.

  The return carriage beam 32 is fixed in the hoistway and has a substantially flat upper plate 32a and a substantially flat lower plate 32b. An anti-vibration rubber 21 as a first anti-vibration member is provided on the upper surface 33 u of the upper plate 32 a of the return beam 32. In addition, a vibration isolating rubber 22 as a second vibration isolating member is provided on the upper surface 34 u of the lower plate 32 b of the return wheel 32. The anti-vibration rubbers 21 and 22 are respectively provided on the left and right sides of the central axis C2 of the car-side return wheel 31.

  As shown in FIG. 8, the return wheel 32 has a substantially U-shaped cross section, and has an upper plate 32 a and a lower plate 32 b. The upper plate 32a constitutes an installation part of the equipment stand. The lower plate 32b is provided so as to face the upper plate 32a with a space in the vertical direction, and constitutes a fixed part of the device base.

  On the anti-vibration rubber 21, a return wheel bracket 30 is installed. The return wheel bracket 30 has a substantially U-shaped cross section, and includes a substantially flat upper plate 30a and a substantially flat lower plate 30b. The return wheel bracket 30 supports the car side return wheel 31 so that it can rotate. A rope 8 is wound around the car-side return wheel 31 and extends downward. The extended end of the rope 8 is wound around a vehicle related to the car and the counterweight, or directly suspends the car and the counterweight. The car-side return wheel 31 constitutes a sheave, and the return wheel bracket 30 constitutes an elevator device.

  The return wheel bracket 30 is provided with a through bolt 202. The through bolt 202 includes an upper plate 30 a of the return wheel bracket 30, a lower plate 30 b of the return wheel bracket 30, an anti-vibration rubber 21, an upper plate 32 a of the return wheel 32, an anti-vibration rubber 22, and a lower plate of the return wheel 32. 32b is penetrated. The through bolt 202 uses the washer 17 and the double nut 18 to fix the vibration isolating rubber 22 to the upper surface 34u of the lower plate 32b. Further, the through bolt 202 fixes the return wheel bracket 30 by using the double nut 18 on the lower surface of the upper plate 30a. The through bolt 202 and the anti-vibration rubbers 21 and 22 are provided one on each of the left and right sides of the car-side return wheel 31.

  Below, the effect | action of the elevator apparatus by Embodiment 3 is demonstrated using FIG.

  The own weights of the car-side return wheel 31 and the return wheel bracket 30 are supported by the anti-vibration rubber 21 directly below the return wheel bracket 30 and act on the anti-vibration rubber 21 as a compression load.

  On the other hand, the load acting on the car-side return wheel 31 from the car and the counterweight acts downward as indicated by the arrow P13 in FIGS. This load acts on the return wheel bracket 30. The load acting on the return wheel bracket 30 is distributed to the vibration proof rubber 21 and the vibration proof rubber 22 through the through bolts 202 and acts as a compression load on each.

Thus, in the elevator apparatus according to the third embodiment, the vibration isolating rubbers 21 and 22 that support the load from the car and the counterweight are arranged above and below, so that the area of the vibration isolating rubber viewed in plan is reduced. Can be small.
In other words, the first vibration isolation member and the second vibration isolation member are arranged above and below via the through bolts. Thereby, the vibration isolating member can be arranged in a space saving plane.

  When a horizontal load due to an earthquake acts on the car-side return wheel 31 and the return wheel bracket 30, the load acts as a compressive load on the anti-vibration rubber 21 and the anti-vibration rubber 22 via the through bolts 202. Can be suppressed.

  Further, since the through bolt 202 penetrates the return wheel 32 in the vertical direction, the through bolt 202 diagonally contacts the upper plate 32 a and the lower plate 32 b of the return wheel 32. Therefore, the members constituting the upper plate 32a and the lower plate 32b of the return wheel 32 serve as a stopper that receives a shake against an earthquake, thereby suppressing the displacement of the car-side return wheel 31 and the return wheel bracket 30. it can.

Embodiment 4 FIG.
In the fourth embodiment, a case where the present invention is applied to the car suspension wheel 13 in FIG. 1 will be described with reference to FIG. The arrangement of the anti-vibration member in the fourth embodiment is the same as that in which the arrangement of the anti-vibration member of the car-side return wheel described in the third embodiment is turned upside down.

  FIG. 9 is a front view showing the configuration around the car suspension vehicle in the fourth embodiment of the present invention.

  The car 2 is supported by a lower frame (not shown). The lower frame is connected to the upper frame 42 by two vertical frames 42l and 42r. The upper frame 42 constitutes a device base. The upper frame 42 includes a substantially flat lower plate 42a and a substantially flat upper plate 42b. The lower plate 42a constitutes an installation part of the device base. The upper plate 42b is provided to face the lower plate 42a with an interval in the vertical direction, and constitutes a fixed part of the device base. A vibration isolating rubber 21 as a first vibration isolating member is provided on the lower surface 43d of the lower plate 42a. An anti-vibration rubber 22 as a second anti-vibration member is provided on the lower surface 44d of the upper plate 42b.

  Under the anti-vibration rubber 21, a car suspension bracket 40 is installed. The car suspension bracket 40 includes a substantially flat upper plate 40b and a substantially flat lower plate 40a. The car suspension bracket 40 supports the car suspension truck 41 so that it can rotate. A rope 8 is wound around the car suspension wheel 41 and extends upward. The car suspension vehicle 41 constitutes a sheave, and the car suspension vehicle bracket 40 constitutes an elevator device.

  The car suspension bracket 40 is provided with through bolts 203. The through bolt 203 includes a lower plate 40a of the car suspension bracket 40, an upper plate 40b of the car suspension bracket 40, a vibration isolating rubber 21, a lower plate 42a of the upper frame 42, a vibration isolating rubber 22, and an upper plate of the upper frame 42. It penetrates 42b. The through bolt 203 uses the washer 17 and the double nut 18 to fix the anti-vibration rubber 22 to the lower surface 44d of the upper plate 42b. In addition, the through bolt 203 fixes the car suspension bracket 40 on the upper surface of the lower plate 40a using the double nut 18. As in the case of the third embodiment, the through bolt 203 and the anti-vibration rubbers 21 and 22 are provided one on each of the left and right sides of the central axis C3 of the car suspension vehicle 41. There is one each on the front and back.

  Below, the effect | action of the elevator apparatus by Embodiment 4 is demonstrated using FIG.

  The load acting on the car suspension wheel 41 from the car and the counterweight acts upward as indicated by the arrow P14 in FIG. This load acts on the car suspension bracket 40. The load acting on the car suspension bracket 40 is distributed to the vibration proof rubber 21 and the vibration proof rubber 22 through the through bolts 203 and acts as a compression load on each.

As described above, in the elevator apparatus according to the fourth embodiment, the vibration isolating rubbers 21 and 22 that support the load from the car and the counterweight are arranged above and below, so that the area of the vibration isolating rubber viewed in plan is reduced. Can be small.
In other words, the first vibration isolation member and the second vibration isolation member are arranged above and below via the through bolts. Thereby, the vibration isolating member can be arranged in a space saving plane.

  When a horizontal load due to an earthquake acts on the car suspension vehicle 41 and the car suspension bracket 40, the load acts as a compressive load on the vibration isolation rubber 21 and the vibration isolation rubber 22 via the through bolt 203, and in the horizontal direction. Can be suppressed.

  Since the through bolt 203 penetrates the upper frame 42 vertically, it contacts the lower plate 42a and the upper plate 42b of the upper frame 42 diagonally. Therefore, the members constituting the lower plate 42a and the upper plate 42b of the upper frame 42 serve as stoppers that receive shaking against an earthquake, and the displacement of the car suspension vehicle 41 and the car suspension bracket 40 can be suppressed. .

2 car, 3 counterweight, 4 hoisting machine (equipment for elevator), 5 drive sheave (sieve), 6 hoisting machine stand (equipment stand), 6a upper blade (installing part) ), 6b Lower blade (fixed part) of the hoisting machine base support plate, 20, 201, 202, 203 Through bolt, 21 Anti-vibration rubber (first anti-vibration member), 22 Anti-vibration rubber (second anti-vibration) Member), 29 Through-hole part of through bolt (lifting point), 30 Return wheel bracket (Elevator equipment), 31 Car side return wheel (Sheave), 32 Return wheel (Equipment stand), 32a Upper plate of return wheel (Installation part), 32b Lower plate (fixed part) of return car beam, 33u Upper surface of installation part, 34u Upper surface of fixed part, 40 Car suspension bracket (Elevator equipment), 41 Car suspension car (sheave), 42 Frame (equipment stand), 42a Lower plate (installation part) of upper frame, 42b Upper frame Upper plate (fixed portion), 43d Lower surface of installation portion, 44d Lower surface of fixed portion, 51, 52 Anti-vibration rubber (third anti-vibration member), 61 Hoisting machine base upper plate (installation portion), 61d Upper blade Lower surface (lower surface of installation part), upper surface of 61u hoisting machine base plate (upper surface of installation part), 62 hoisting machine base support plate, 62d lower surface of lower blade (lower surface of fixed part), 71 hoisting machine base Upper plate (installation unit), 71u Upper surface of hoisting machine base upper plate (upper surface of installation unit), 73 Hoisting machine base lower plate (fixing part), 73d Lower surface of hoisting machine base lower plate (lower surface of fixing part) 73u The upper surface of the lower plate of the hoisting machine base (the upper surface of the fixed part).

Claims (2)

An elevator apparatus having a sheave on which a load from a car and a counterweight acts;
An equipment base having an installation part provided with the elevator equipment and a fixing part provided to face the installation part with an interval in the vertical direction;
A first vibration isolation member and a third vibration isolation member provided on one of the installation portion and the fixing portion;
A second vibration isolating member provided on the other side;
A through bolt passing through the first vibration isolation member , the second vibration isolation member, and the third vibration isolation member ;
The installation portion and the fixing portion each have an upper surface and a lower surface,
When the first vibration isolation member is provided on the lower surface of the installation portion, the second vibration isolation member is provided on the lower surface of the fixing portion,
When the first vibration isolation member is provided on the upper surface of the fixed portion, the second vibration isolation member is provided on the upper surface of the installation portion,
When the first vibration isolation member is provided on the lower surface of the installation portion, the third vibration isolation member is provided on the upper surface of the installation portion,
When the first vibration isolation member is provided on the upper surface of the fixed portion, the third vibration isolation member is provided on the lower surface of the fixed portion,
The elevator apparatus with which the said apparatus for elevators is fixed to the said apparatus stand by the said penetration bolt via the said 1st vibration isolator , the said 2nd anti-vibration member, and the said 3rd anti-vibration member . An elevator apparatus having a sheave on which a load from a car and a counterweight acts;
An equipment base having an installation part provided with the elevator equipment and a fixing part provided to face the installation part with an interval in the vertical direction;
A first vibration isolation member provided on one of the installation part and the fixing part;
A second vibration isolating member provided on the other side;
A through bolt penetrating the first vibration isolation member and the second vibration isolation member;
The installation portion and the fixing portion each have an upper surface and a lower surface,
When the first vibration isolation member is provided on the lower surface of the installation portion,
The second vibration isolating member is provided on the lower surface of the fixing portion;
When the first vibration isolation member is provided on the upper surface of the fixed portion,
The second vibration isolating member is provided on the upper surface of the installation portion;
The elevator equipment is fixed to the equipment stand by the through bolts via the first vibration isolation member and the second vibration isolation member,
Wherein the upper portion of the through bolts is provided a lifting priority for Agekasane the device and the device table for the elevator Rue elevators device.

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