KR102562388B1 - Supporting bracket for elevator - Google Patents

Abstract

The present invention relates to a load-bearing bracket for installation of an elevator hoist, and provides a firm fixing force and supporting force for the first and second guide rails without separately configuring a seating portion or a seating groove on the inner wall for elevator installation, thereby reducing the installation space of the inner wall Its purpose is to improve durability while minimizing it.
To this end, the present invention is configured at the top of the first and second guide rails, the hoist is configured at the top, and the load-bearing bracket for installation of the elevator hoist to support the lifting of the elevator car and the counterweight along the first and second guide rails. contains; The load-bearing bracket for installation of the elevator hoist is a main frame configured on top of the first and second guide rails; and a longitudinal axis reinforcing frame configured to provide bearing force to the main frame, which is configured in a longitudinal direction at a lower end of the main frame; The main frame includes at least one first insertion groove formed to penetrate with a predetermined width, and a first access hole formed to pass through so that the hoisting rope of the hoisting machine can enter and exit; The longitudinal axis reinforcing frame is formed to protrude at a predetermined height at one end and is inserted into the first insertion groove of the main frame, and at least one first insertion protrusion supporting it to be assembled to the main frame; characterized in that it includes.

Description

Supporting bracket for elevator installation

The present invention relates to a load-bearing bracket for installation of an elevator hoist, and more particularly, by providing a firm fixing force and bearing force for the first and second guide rails without separately configuring a seating portion or a seating groove on the inner wall for elevator installation, It relates to a load-bearing bracket for installation of an elevator hoist to improve durability while minimizing the installation space of the inner wall.

In general, an elevator device installed for vertical movement of people or objects in a building constructed for residential or business purposes has a separate machine room and a hoisting machine is installed therein, or an elevator without a machine room inside the hoistway. After installing the traction machine, the elevator car can be operated in the up and down directions by controlling the main rope wound around the main sheave of the traction machine to selectively move.

On the other hand, by removing the machine room, the problem of designing and installing a separate machine room during the construction of the building is solved, and the installation of an elevator device without a machine room is increasing to facilitate building extension and elevator maintenance work. It is a trend that is becoming

Looking at a conventional example, in the installation structure of the elevator hoist of Patent No. 10-455502, as shown in FIG. 1, a portion of the uppermost layer of the inner wall 1 of the hoistway is made in a substantially rectangular shape, so that the hatch door side of the elevator platform or the top of the hatch track After the seating portion 2 formed to penetrate the side surface is configured, a sound absorbing material is attached to the rear side of the elevator landing and an opening and closing door having a shape similar to that of the seating portion 2 is formed to selectively open the seating portion 2. It is configured so that it can be opened or closed.

In addition, the elevator hoist 10 is installed inside the seating portion 2. In installing the hoisting machine 10 in the seating portion 2, the horizontal to a point having a certain height of the seating portion 2 After the fixing beam 3 is fixedly installed in the direction, the hoisting machine 10 is positioned between the bottom surface of the seating part 2 and the fixing beam 3 to be installed.

In addition, on the upper side of the seating part 2, the first hitch beam 4 and the second hitch beam 5 fixed to the inner wall 1 of the hoistway, respectively, are installed in parallel with both ends facing each other, so that the hoisting machine It is configured to fix both ends of the main rope 12 wound around the main sheave of (10) and a plurality of idler sheaves 14 for changing the direction of the main rope 12.

At this time, in order to fix the first and second hitch beams 4 and 5 to the inner wall 1 of the hoistway, a seating groove 20 having a certain depth is formed in the inner wall 1, and the seating groove 20 Both ends of the first and second hitch beams 4 and 5 are inserted into , so that the first and second hitch beams 4 and 5 are fixed to the inner wall 1 of the hoistway.

In addition, an elevator car 30 is positioned on the inner wall 1 of the hoistway, and a first guide rail 32 guiding the elevator car 30 ascends and descends.

In addition, a balance weight 34 supporting the elevation of the elevator car 30 is formed on the inner wall 1 of the hoistway, and a second guide rail 36 supporting the elevation of the balance weight 34 is formed.

In addition, the lower ends of the first and second guide rails 32 and 36 are erected vertically from the bottom surface of the inner wall 1 of the hoistway, and the upper ends are fixed to the first and second hitch beams 4 and 5. It is composed so that

Accordingly, as shown in FIG. 1B, an installation space S in which the idler sheave 14 is installed along with the first and second hitch beams 4 and 5 is essentially formed at the upper end of the inner wall 1 of the hoistway. .

However, as described above, in the conventional elevator installation structure, there is a hassle in construction in that the seating part 2 to which the hoisting machine 10 is to be installed is separately formed on one side of the inner wall 1 of the hoistway.

That is, after curing the concrete to construct the inner wall 1 of the hoistway, a separate operation for forming the seating portion 12 on the inner wall 1 of the hoistway is troublesome.

In addition, at the upper end of the inner wall 1 of the hoistway, it is cumbersome to construct a separate seating groove 20 having a certain depth to support both ends of the first and second hitch beams 4 and 5 to be inserted. there is

In addition, the first and second hitch beams 4 and 5 support the plurality of idler sheaves 14 and have rigidity capable of withstanding the load of the elevator car 30. By being formed of a steel beam, there is a problem that the manufacturing cost is increased.

In addition, as described above, the inner wall 1 of the hoistway has a certain depth for supporting the seating portion 12 of a certain space where the hoisting machine 10 is seated and the first and second hitch beams 4 and 5. Since the seating groove 20 is essentially formed, the durability of the inner wall 1 of the hoistway is lost as much as the space between the seating portion 12 and the seating groove 20 is lost. Accordingly, in order to compensate for the lost durability of the hoistway inner wall 1, the thickness of the hoistway inner wall 1 needs to be increased, which increases the amount of concrete injected, thereby increasing the construction cost.

Republic of Korea Patent Publication No. 10-455502 (2004.11.06. Notice) Republic of Korea Patent Publication No. 10-1902134 (2018.09.27. Notice)

As proposed to solve the above problems, an object of the present invention is to provide a firm fixing force and supporting force for the first and second guide rails without separately configuring a seating portion or a seating groove on the inner wall for elevator installation, It is to provide a load-bearing bracket for installation of an elevator hoist to improve durability along with minimizing the installation space of the inner wall.

As proposed to achieve the above object, the present invention is configured at the top of the first and second guide rails, the hoist is configured at the top, and the elevator car and the counterweight are configured along the first and second guide rails. Including a load-bearing bracket for installation of the elevator hoist to support the elevation; The load-bearing bracket for installation of the elevator hoist is a main frame configured on top of the first and second guide rails; and a longitudinal axis reinforcing frame configured to provide bearing force to the main frame, which is configured in a longitudinal direction at a lower end of the main frame; The main frame includes at least one first insertion groove formed to penetrate with a predetermined width, and a first access hole formed to pass through so that the hoisting rope of the hoisting machine can enter and exit; The longitudinal axis reinforcing frame is formed to protrude at a predetermined height at one end and is inserted into the first insertion groove of the main frame, and at least one first insertion protrusion supporting it to be assembled to the main frame; characterized in that it includes.

In the present invention, the load-bearing bracket for installation of the elevator hoist includes a first supporting reinforcing frame configured on one side of the upper end of the main frame to improve reinforcing force for the hoist mounted on the upper end of the main frame; The first supporting reinforcing frame has a second entrance hole formed to penetrate at a position corresponding to the first entrance hole of the main frame, and a first fastening hole formed in the main frame so as to be fastened and fixed to the main frame by a fastening means, It includes a third fastening hole formed at a position corresponding to the first fastening hole, and a fourth fastening hole for supporting the hoisting machine seated on the upper end to be fixed by the fastening means; It is preferable to include; between the main frame and the first supporting reinforcing frame, a vibration-proof pad supporting to absorb vibration generated from the hoisting machine to improve durability of the load-bearing bracket.

In the present invention, the main frame includes a second support reinforcement frame configured at one side of the upper end of the main frame to enhance durability of the counterweight socket; and a third supporting reinforcing frame formed on the other side of the upper end of the main frame and configured to reinforce bearing force for the second guide rail formed on one side of the lower end of the main frame.

In the present invention, it is configured between the main frame and the longitudinal reinforcing frame, and includes a first reinforcing rib for supporting the upper end of the second guide rail to be fixed; The first reinforcing rib is formed on one side and has a sixth fastening hole for supporting the upper end of the second guide rail configured on the hoisting machine side to be fixed by a fastening means, and a second insertion groove protruding from the upper end at a predetermined height and formed in the main frame. A first insertion protrusion inserted into and supported to maintain the assembled state, and a fourth insertion groove protruding at a certain height from one end located on one side of the longitudinal axis reinforcing frame to be inserted into the fourth insertion groove formed in the longitudinal axis reinforcing frame to support to maintain the assembled state It is preferable to include; second insertion protrusion.

In the present invention, it is constructed between the main frame and the longitudinal reinforcing frame, and includes a second reinforcing rib for reinforcing the reinforcing force between the main frame and the longitudinal reinforcing frame; The second reinforcing rib protrudes at a certain height from the top and is inserted into the third insertion groove formed in the main frame to support the third insertion protrusion to maintain the assembled state, and protrudes at a certain height from one end located on one side of the longitudinal axis reinforcing frame It is inserted into the fifth insertion groove formed in the longitudinal axis reinforcing frame and the fourth insertion protrusion for supporting to maintain the assembled state; it is preferable to include.

According to the present invention, by providing a firm fixing force and supporting force for the first and second guide rails without separately configuring a seating portion or a seating groove on the inner wall for elevator installation, the installation space of the inner wall is minimized and durability is improved. It has the effect of letting go.

Figures 1a and 1b is an elevator installation structure diagram showing an example of the prior art.
2 is a block diagram of a load-bearing bracket for installing an elevator hoist according to the present invention;
2a is a front view, 2b is a side view.
3 is a perspective view of a load-bearing bracket according to the present invention;
3a is a front perspective view, 3b is a bottom perspective view.
Figure 4 is an exploded perspective view of the load-bearing bracket according to the present invention.
Figure 5 is a bottom view of the bearing bracket according to the present invention.
6 is a plan view of a mainframe according to the present invention;
Figure 7 is a front view of the longitudinal axis reinforcing frame according to the present invention.
Figure 8 is a plan view of the first reinforcing support frame according to the present invention.
Figure 9 is a plan view of the second support reinforcement frame according to the present invention.
Figure 10 is a plan view of a third supporting reinforcing frame according to the present invention.
11 is a side view of a first reinforcing rib according to the present invention;
12 is a view of a second reinforcing rib according to the present invention,
12a is a counterweight socket rib and a counterweight rail reinforcement rib, and 12b is an elevator car side rib.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings (the same reference numerals are used for the same components as in the prior art, and detailed descriptions thereof are omitted).

As shown in FIGS. 2 and 3, the load-bearing bracket 100 of the present invention is configured on top of the first and second guide rails 32 and 36 configured on the inner wall 1 for elevator installation, and the Space utilization and inner wall (1) by minimizing the installation space (S) of the elevator by strengthening the bearing capacity for the first and second guide rails (32, 36) and supporting the support of the hoisting machine (10) to improve the durability of

As shown in FIGS. 4 and 5, the load-bearing bracket 100 includes a main frame 110, a longitudinal axis reinforcing frame 120, and first to third supporting reinforcing frames 130, 140, and 150. and the first to third reinforcing ribs 160, 170, and 180, but formed in a prefabricated manner, thereby minimizing the welding area for each component and minimizing the effect on thermal deformation of welding. to improve durability.

The main frame 110 is configured at the upper end of the first and second guide rails 32 and 36 to provide support for the first and second guide rails 32 and 36, thereby providing support for the first and second guide rails 32 and 36. The vertical supporting force of the second guide rails 32 and 36 is compensated.

The main frame 110 is formed in a flat plate shape.

As shown in FIG. 6, the main frame 110 has a first insertion groove 112 that is formed to penetrate at both ends of a predetermined size and supports each of both ends of the longitudinal axis reinforcing frame 120 to be assembled. is formed The first insertion groove 112 is formed to penetrate at a predetermined length from both ends of the main frame 110, that is, from both ends in the longitudinal direction to the inside, and one end of the longitudinal axis reinforcing frame 120 is inserted, thereby causing the main frame to be inserted. The vertical axis reinforcing frame 120 is supported in (110) to maintain the assembled state. In addition, the first insertion groove 112 is not limited to being formed at both ends of the main frame 110, and one end of the longitudinal axis reinforcing frame 120, for example, is inserted into the longitudinal axis of the main frame 110 as the central portion is inserted. A plurality may be configured in the center or at regular intervals so that the fixing force by the assembly of the reinforcing frame 120 is expanded.
In addition, the main frame 110 is formed with a first hoisting entry/exit hole 114 for supporting the hoisting rope of the hoisting machine 10 seated on the upper end to enter and exit. The first hoisting entry/exit hole 114 is configured to pass through both sides of the main frame 110 with a certain width, so that the hoisting rope of the hoisting machine 10 seated on the top of the main frame 110 can smoothly enter and exit. support so that

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In addition, a second insertion groove 116 is formed in the main frame 110 so that one side of the first reinforcing rib 160 is inserted and fixed by assembly. The second insertion groove 116 is configured to pass through each of both ends of the main frame 110, and as one side of the first reinforcing rib 160 is inserted, the first reinforcing rib 160 in the main frame 110 support to fix it.

In addition, a third insertion groove 118 is formed in the main frame 110 so that one side of the second reinforcing rib 170 is inserted and fixed by assembly. The third insertion groove 118 is formed at regular intervals along the longitudinal direction of the main frame 110, and one side of the second reinforcing rib 170 is inserted into the second reinforcing rib 170 in the main frame 110. ) to be fixed.

In addition, the main frame 110 includes at least one first fastening hole 119 for supporting the first supporting reinforcing frame 130 seated on the top so that the reinforcing force is improved by a firm coupling by a fastening means. The first fastening hole 119 is formed in the main frame 110 so that the first supporting reinforcing frame 130 is fixed to the main frame 110 by a fastening means. In this case, the first fastening hole 119 is formed in a portion located at the corner of the first supporting reinforcing frame 130 . In addition, the fastening means is composed of a bolt and a nut, and may be composed of a spring washer or a washer for absorbing vibration. Of course, it is not limited to this, and any fastening means can be employed as long as it has a configuration or structure that prevents arbitrary loosening of the first support reinforcing frame 130 in the main frame 110 due to vibration or impact of the hoisting machine 10. do.

The longitudinal axis reinforcing frame 120 is configured on one end surface, that is, the bottom surface of the main frame 110, and performs a function of providing vertical supporting force to the main frame 110.

The longitudinal axis reinforcing frame 120 is formed in a flat plate shape.

As shown in FIG. 7, the longitudinal axis reinforcing frame 120 includes a first insertion protrusion 122, a fourth insertion groove 124, a fifth insertion groove 126, and a second fastening hole 128. includes

The first insertion protrusion 122 protrudes at a certain height at the top and is inserted into the first insertion groove 112 of the main frame 110, so that the longitudinal axis reinforcing frame 120 is prefabricatedly coupled to the main frame 110 support as much as possible In this case, the height of the first insertion protrusion 122 is equal to or slightly smaller than the thickness of the main frame 110 so that it does not protrude to the top of the main frame 110 when inserted into the first insertion groove 112. formed in height. In addition, the first insertion protrusions 122 are formed in the same number as the first insertion grooves 112 .

The fourth insertion groove 124 supports one end surface of the first reinforcing rib 160 so that it can be assembled in close contact. That is, the fourth insertion groove 124 is formed at a position to provide a supporting force for the portion where the hoist is seated at the top of the main frame 110, and is formed to penetrate with a certain width, so that the first One end of the reinforcing rib 160 is inserted so that the first reinforcing rib 160 is assembled and coupled to the longitudinal axis reinforcing frame 120.

The fifth insertion groove 126 supports one end surface of the second reinforcing rib 170 so that it can be assembled in close contact. That is, the fifth insertion groove 126 is formed at a position to provide a supporting force to the position where the balance weight is formed, and is formed to penetrate with a certain width, so that one end of the second reinforcing rib 170 To be inserted, so that the second reinforcing rib 170 is assembled and coupled to the longitudinal axis reinforcing frame 120.

The second fastening hole 128 supports one end, that is, the upper end of the first guide rail 32 to be fastened and fixed to the longitudinal axis reinforcing frame 120 by a fastening means. In this case, the fastening means fastened to the second fastening hole 128 is composed of a bolt, a nut, a spring washer, or a shock absorbing washer.

The first supporting reinforcing frame 130 is configured on one side of the upper end of the main frame 110 and performs a function of supporting so that the supporting force for the traction machine 10 seated on the upper end is reinforced.

As shown in FIG. 8, the first supporting reinforcing frame 130 is formed with a second hoisting entry/exit hole 132 supporting the hoisting rope of the hoisting machine 10 seated on the upper end to enter and exit. The second hoisting entry/exit hole 132 is configured to pass through both sides of the first supporting reinforcing frame 130 with a certain width, and the hoisting rope of the hoisting machine 10 seated on the upper end of the first supporting reinforcing frame 130 support for smooth entry and exit. In this case, the second hoisting entry and exit hole 132 is formed at a position corresponding to the first hoisting entry and exit hole 114 of the main frame 110, so that the hoisting machine 10 can smoothly enter and exit the hoisting rope. .

In addition, the first fastening means 210 is inserted into the first supporting reinforcing frame 130, and the first supporting reinforcing frame 130 is attached to the main frame 110 by the fastening force of the first fastening means 210. It includes a third fastening hole 134 for supporting so that it can be firmly fixed. In this case, the third fastening hole 134 is formed at the corner of the first supporting reinforcing frame 130 and is formed at a position corresponding to the first fastening hole 119 of the main frame 110 .
In addition, the first fastening means 210 is inserted into the third fastening hole 134 of the first supporting reinforcing frame 130 and the first fastening hole 119 of the main frame 110, as shown in FIG. As each of the first support reinforcing frame 130 and the stay bolts 212 protruding at a certain height from the main frame 110 are fastened to both ends of the protruding stay bolts 212, the first support reinforcing frame 130 It consists of a lock nut 214 that supports so that a fixing force acts between the ) and the main frame 110.
Accordingly, the first fastening means 210 provides a fixing force between the first support reinforcing frame 130 and the main frame 110, and provides a fastening force between the first support reinforcing frame 130 and the main frame 110. By supporting such that the distance is maintained, it is possible to absorb vibration or shock generated from the hoisting machine 10 seated on the first supporting reinforcing frame 130. Eventually, by maintaining the distance between the first support reinforcing frame 130 and the main frame 110 through the first fastening means 210, the traction machine 10 ) With the protection of, to prevent or minimize the transmission of vibration or shock of the hoisting machine 10 to the main frame 110 so as to improve the durability of the load-bearing bracket 100.

In addition, the first supporting reinforcing frame 130 is formed with a fourth fastening hole 136 for supporting the hoisting machine 10 seated on the upper end to be fastened and fixed by the second fastening means 220. The fourth fastening hole 136 is formed to pass through the first supporting reinforcing frame 130 so that it can be fixed by the second fastening means 220 according to the shape or size of the hoisting machine 10 . In this case, the main frame 110 configured at the lower end of the first supporting reinforcing frame 130 is formed to penetrate at a position corresponding to the fourth fastening hole 136, so that the second fastening means 220 The first support reinforcing frame 130 is supported so that the hoist 10 is fixed to the top of the support reinforcing frame 130, and the first support reinforcing frame 130 is firmly fixed to the main frame 110.
In addition, the second fastening means 220 is composed of a hexagonal bolt and a nut, as shown in FIG. 2A. Of course, it is not limited to this, and the second fastening means 220 can employ any configuration as long as it can support that the hoisting machine 10 is firmly fixed to the third supporting reinforcing frame 130.

In addition, as shown in FIG. 4, the first support reinforcing frame 130 is configured between the main frame 110 and the first support reinforcing frame 130 to absorb vibration generated by the operation of the hoisting machine 10. It includes an anti-vibration pad 137 to In this case, the anti-vibration pad 137 may be configured between the hoisting machine 10 and the first supporting reinforcing frame 130 .

The antivibration pad 137 is configured at the lower end of the first supporting reinforcing frame 130 to absorb vibration generated by the operation of the hoisting machine 10 to prevent the durability of the load bearing bracket 100 from deteriorating. Rubber, It is made of silicone or synthetic resin. In this case, the anti-vibration pad 137 is formed with a certain width at the position where the fourth fastening hole 136 is formed, and a through hole is formed in the center so that the second fastening means 220 can be inserted. That is, the anti-vibration pad 137 is configured between the main frame 110 and the first support reinforcing frame 130, and the hoisting machine 10 is formed by the second fastening means 220 inserted into the fourth fastening hole 136. ), the first support reinforcing frame 130, the anti-vibration pad 137, and the main frame 110 are fastened and fixed together. An insertion hole into which the second fastening means 220 is inserted is formed in the center.

The second supporting reinforcing frame 140 is configured at the upper end of the main frame 110 and serves to reinforce the counterweight socket.

The second supporting reinforcing frame 140 is formed in a flat plate shape having a predetermined thickness.

In addition, as shown in FIG. 9, the second supporting reinforcing frame 140 is fixed to the main frame 110 by means of fastening means, and a fifth fastening hole 142 is formed to support the counterweight socket to be fixed. do.

As shown in FIG. 10, the third support reinforcing frame 150 is configured on one side of the upper end of the main frame 110 to apply reinforcing force to the top of the counterweight rail, that is, the part to which the second guide rail 36 is fixed. to strengthen In this case, the third supporting reinforcing frame 150 is fixed to the main frame 110 by a thermal fusion method such as welding. Of course, it is not limited thereto, and the third supporting reinforcing frame 150 can be fixed to the main frame 110 using fastening means such as rivets, bolts and nuts, and the main frame 110 3 Any structure, configuration or means capable of stably fixing the supporting reinforcing frame 150 can be employed.

The first reinforcing rib 160 is configured between the main frame 110 and the longitudinal axis reinforcing frame 120, and supports the upper end of the second guide rail to be fixed by the fastening means.

As shown in FIG. 11, one end surface of the second guide rail 36 is in close contact with the first reinforcing rib 160, and the second guide rail A plurality of sixth fastening holes 162 are formed to support the upper end of 36 to be firmly fixed.

The sixth fastening hole 162 is formed to pass through the first reinforcing rib 160 in plurality, so that the upper end of the second guide rail 36 is firmly fixed through the fastening means. That is, the sixth fastening hole 162 allows the upper end of the second guide rail 36 to be firmly fixed to one end surface of the first reinforcing rib 160 by a fastening means, so as in the prior art, thermal fusion such as welding. When the second guide rail 36 is fixed to the first reinforcing rib 160 by a method, a decrease in stress due to a vertical load due to thermal deformation is prevented.

In addition, the first reinforcing rib 160 is formed at a certain height on the upper surface in close contact with the lower surface of the main frame 110 based on the installation state, and the second insertion groove 116 of the main frame 110 ) A second insertion protrusion 164 is formed.

The second insertion protrusion 164 is formed at a predetermined height from the top surface of the first reinforcing rib 160 and is inserted into the second insertion groove 116 of the main frame 110, so that the main frame 110 The first reinforcing rib 160 is supported to maintain a firmly fixed state. In this case, the protruding height of the second insertion protrusion 164 is equal to the thickness of the main frame 110 or formed to a slightly smaller length, so that the second insertion protrusion 164 protrudes to the top of the main frame 110. do not become

In addition, the first reinforcing rib 160 is formed to protrude with a certain length on one side that is in close contact with one end surface of the longitudinal axis reinforcing frame 120 based on the installation state, and the fourth of the longitudinal axis reinforcing frame 120 A third insertion protrusion 166 inserted into the insertion groove 124 is formed.

The third insertion protrusion 166 is formed to a certain length on one side of the first reinforcing rib 160 and is inserted into the fourth insertion groove 124 of the longitudinal axis reinforcing frame 120, so that the longitudinal axis reinforcing frame ( 120) to support the first reinforcing rib 160 to maintain a firmly fixed state. In this case, the protruding height of the third insertion protrusion 166 is equal to the thickness of the longitudinal axis reinforcing frame 120, or formed to a slightly smaller length, so that the third insertion protrusion 166 is the other side of the longitudinal axis reinforcing frame 120. Make sure it does not protrude into the cross section.

The second reinforcing rib 170 is configured between the main frame 110 and the vertical axis reinforcing frame 120, and provides a reinforcing force to stably support a load acting by a counterweight or the like configured at the upper end of the main frame 110. to provide.

As shown in FIG. 12, the second reinforcing rib 170 is formed at a certain height on the upper surface in close contact with the lower surface of the main frame 110 based on the installation state, A fourth insertion protrusion 172 inserted into the third insertion groove 118 is formed.

The fourth insertion protrusion 172 is formed at a certain height from the top surface of the second reinforcing rib 170 and is inserted into the third insertion groove 118 of the main frame 110, so that the main frame 110 The second reinforcing rib 170 is supported to maintain a firmly fixed state. In this case, the protruding height of the fourth insertion protrusion 172 is equal to the thickness of the main frame 110 or formed to a slightly smaller length, so that the fourth insertion protrusion 172 protrudes to the top of the main frame 110. do not become

In addition, the second reinforcing rib 170 is formed to protrude with a certain length on one side that is in close contact with one end surface of the longitudinal axis reinforcing frame 120 based on the installation state, and the fifth of the longitudinal axis reinforcing frame 120 A fifth insertion protrusion 174 inserted into the insertion groove 126 is formed.

The fifth insertion protrusion 174 is formed to a certain length on one side of the second reinforcing rib 170 and is inserted into the fifth insertion groove 126 of the longitudinal axis reinforcing frame 120, so that the longitudinal axis reinforcing frame ( 120) to support the second reinforcing rib 170 to maintain a firmly fixed state. In this case, the protruding height of the fifth insertion protrusion 174 is equal to the thickness of the longitudinal axis reinforcing frame 120, or formed to a slightly smaller length, so that the fifth insertion protrusion 174 is the other of the longitudinal axis reinforcing frame 120. Make sure it does not protrude into the cross section.

The second reinforcing rib 170 is divided into a counterweight socket rib 1762, an elevator car side rib 1764, and a second guide rail reinforcing rib 1766 according to the configuration position.

As shown in FIG. 12A, the counterweight socket rib 1762 serves to reinforce the supporting force for the load acting on the counterweight socket formed at the upper end of the main frame 110. In this case, the counterweight socket ribs 1762 are configured at the lower end of the main frame 110, and are configured in plurality so as to support each of both ends of the second supporting reinforcing frame 140 configured at the upper end of the main frame 110 do.

As shown in FIG. 12B, the elevator car side rib 1764 serves to reinforce the supporting force for the load acting on the hoisting machine 10 configured at the top of the main frame 110. In this case, the elevator car side rib 1764 is configured at the lower end of the main frame 110 to support the lower end of the first support reinforcement frame 130 configured at the upper end of the main frame 110.

In addition, the elevator car side ribs 1764 are configured on each side of the longitudinal axis reinforcing frame 120, so that the supporting force for the load acting on the main frame 110 is reinforced.

As shown in FIG. 12A, the second guide rail reinforcing rib 1766 serves to reinforce fixing to the second guide rail configured at one end of the main frame 110. In this case, the second guide rail reinforcing rib 1766 is configured at the lower end of the main frame 110, and is configured to support the lower end of the third supporting reinforcing frame 150 configured at the upper end of the main frame 110 .

On the other hand, the first and second guide rails 32 and 36 configured at the lower end of the main frame 110 are configured to be fixed by a fastening means, so that the first and second guide rails 32 and 36 are thermally deformed by welding, etc., as in the prior art. 2 to prevent the guide rails (32, 36) from being deformed.

In addition, in principle, the load-bearing bracket for installation of the elevator hoist is fixed by the assembly method by the insertion groove and the insertion projection of the main frame 110, the vertical axis reinforcing frame 120, and the first and second reinforcing ribs 160 and 170. In addition, by contacting by intermittent welding or spot welding method, the deformation due to thermal deformation is minimized so that the durability of the load-bearing bracket for installation of the elevator hoist is improved.

The load-bearing bracket 100 configured as described above fixes the main frame 110 to the upper ends of the first and second guide rails by fastening means without separately configuring a seating portion or a seating groove on the inner wall for installing the elevator.

Subsequently, the longitudinal axis reinforcing frame 120 is prefabricatedly fixed to the lower end of the main frame 110, and the first to third support reinforcing frames 130, 140, and 150 are fixed to the upper end of the main frame 110. do.

In addition, at least one or more first and second reinforcing ribs 160 and 170 are fixed between the main frame 110 and the longitudinal axis reinforcing frame 120 in a prefabricated manner.

Through this, as a separate seating groove is not installed on the inner wall, the installation space is minimized, and durability is improved by providing fixing force and supporting force by prefabrication.

What has been described above is only one embodiment for carrying out the load bearing bracket for installation of the elevator hoist, and the present invention is not limited to the above embodiment. Those skilled in the art in the field belonging to the present invention will be able to understand that various modifications are possible without departing from the gist of the present invention.

100: bearing bracket 110: main frame
112: first insertion groove 114: first entrance hole
116: second insertion groove 118: third insertion groove
119: first fastening hole 120: longitudinal axis reinforcement frame
122: first insertion protrusion 124: fourth insertion groove
126: 5 insertion groove 128: 2 fastening hole
130: first support reinforcing frame 132: second winding upper entrance hole
134: third fastening hole 136: fourth fastening hole
137: anti-vibration pad 140: second support reinforcement frame
142: 5 fastening hole 150: 3 support reinforcement frame
160: first reinforcing rib 162: sixth fastening hole
164: first insertion projection 166: first insertion projection
170: second reinforcing rib 172: third insertion protrusion
174: fourth insertion protrusion 1762: counterweight socket rib
1764: elevator car side rib 1766: counterweight rail reinforcement rib

Claims (5)

In the load-bearing bracket for installation of an elevator hoist, which is configured at the top of the first and second guide rails, has a hoist at the top, and is configured to support the lifting of the elevator car and the counterweight along the first and second guide rails,
The load-bearing bracket, the load-bearing bracket for installation of the elevator hoist is configured in the longitudinal direction of the main frame configured at the upper end of the first and second guide rails and the lower end of the main frame, to provide vertical supporting force for the main frame. A longitudinal axis reinforcing frame configured to provide, a first support reinforcing frame configured on one side of the upper end of the main frame and supported so that the supporting force for the traction machine seated on the upper end is reinforced, and a counterweight socket configured on the upper end of the main frame A second supporting reinforcing frame for reinforcing, a third supporting reinforcing frame configured on one side of the upper end of the main frame to reinforce the reinforcing force at the upper end of the part to which the second guide rail is fixed, and the main frame and the longitudinal reinforcing frame The load of the first reinforcing rib, which is formed between the first reinforcing rib and is formed between the main frame and the longitudinal axis reinforcing frame to support the upper end of the second guide rail to be fixed by the fastening means, and is formed at the upper end of the main frame, stably It consists of a second reinforcing rib that provides reinforcing force to support;
The main frame is formed in a flat plate shape, and is formed to penetrate at both ends to have a predetermined size so that each of both ends of the longitudinal axis reinforcing frame can be assembled, and the first insertion groove is formed, and the hoisting rope of the hoisting machine seated on the top can enter and exit. A first hoisting entry/exit hole formed so that one side of the first reinforcing rib is inserted into a second insertion groove formed so that one side of the first reinforcing rib can be inserted and fixed by assembly, and one side of the second reinforcing rib is inserted and fixed by assembly It includes a third insertion groove formed to be formed, and a plurality of first fastening holes formed to improve the reinforcing force by fixing the first supporting reinforcing frame seated on the top by the first fastening means;
The longitudinal axis reinforcing frame is formed in a flat plate shape, protrudes at a predetermined height at the top, and is inserted into the first insertion groove of the main frame to support the longitudinal axis reinforcing frame to be prefabricatedly coupled to the main frame. 4th insertion groove for assembling the first reinforcing rib to the longitudinal axis reinforcing frame by inserting one end of the reinforcing rib, and 5th insertion for assembling the second reinforcing rib to the longitudinal axis reinforcing frame by allowing one end of the second reinforcing rib to be inserted It includes a groove, and a second fastening hole for supporting the upper end of the first guide rail to be fixed to the longitudinal axis reinforcing frame by a fastening means;
The first supporting reinforcing frame is formed so that the main frame and the first supporting reinforcing frame are fixed by the second hoisting entry and exit hole formed so that the hoisting rope of the hoisting machine seated at the top can enter and exit, and the first fastening means. A fastening hole, a fourth fastening hole for supporting the hoisting machine seated at the upper end to be fixed by the second fastening means, and a vibration generated by the operation of the hoisting machine configured between the main frame and the first support reinforcing frame. It includes an anti-vibration pad to prevent;
The first fastening means is inserted into the third fastening hole of the first supporting reinforcing frame and the first fastening hole of the main frame, and fastened to each of the both ends of the stay bolts and the stay bolts, each of which is configured to protrude at a predetermined height, It is composed of a lock nut that prevents loosening due to vibration or shock generated by the hoisting machine and supports a buffering action in the interval between the main frame and the first support reinforcing frame formed by the thickness of the anti-vibration pad;
The second fastening means provides a fastening force so that the hoisting machine, the first support reinforcing frame, the anti-vibration pad, and the main frame are fixed;
The second support reinforcing frame is formed in a flat plate shape, and includes a fifth fastening hole formed to fix the counterweight socket to the main frame and to be fixed to the main frame by the fastening means;
The first reinforcing ribs are formed at both ends of the main frame, have a flat plate shape, and are formed on a surface in close contact with the upper end surface of the second guide rail to support the upper end of the second guide rail to be fixed by a fastening means. 6 fastening holes, a second insertion projection inserted into the second insertion groove of the main frame, and a third insertion projection inserted into the fourth insertion groove of the longitudinal axis reinforcing frame;
The second reinforcing rib is composed of a fourth insertion projection inserted into the third insertion groove of the main frame and a fifth insertion projection inserted into the fifth insertion groove of the longitudinal axis reinforcing frame;
The second reinforcing rib includes a counterweight socket rib supporting each of both ends of the second reinforcing frame formed at the top of the main frame to reinforce the bearing force for the load acting on the counterweight socket formed at the top of the main frame, An elevator car side rib configured on each side of the longitudinal axis reinforcing frame to support the lower end of the first supporting reinforcing frame configured at the upper end of the frame, and a third supporting reinforcing frame configured at the upper end of the main frame. 2 guide rail reinforcement ribs;
Load-bearing bracket for installation of the elevator hoist, characterized in that consisting of. delete delete delete delete