JP2007030924A - Vibration-proof pedestal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a collision between loaded articles without using a separate member, and at the same time, to effectively utilize the arranging space of a vibration-proof pallet. <P>SOLUTION: A lower pedestal 12 has protruding sections 55a and 55b which protrude outward from the upper pedestal 11 in the horizontal direction along the edge of an upper pedestal 11. A maximum moving width in the vertical direction of the upper pedestal 12 which is regulated by a stopper is defined as h1, and a maximum moving width in the horizontal direction is defined as W2, the height of a loaded article 60 is defined as H, and an interval between the stoppers which are arranged on both end sides of the upper pedestal 11 is defined as P, the protruding width W of the protruding portions 55a and 55b is regulated in a manner to satisfy a relational formula of H×h1/P+W2≤W≤1.5×(H×h1/P+W2). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vibration isolator that reduces vibration transmission to a load.

  As this type of anti-vibration gantry, an anti-vibration gantry for placing an outdoor unit or the like of an air conditioner, for example, is arranged on a lower gantry fixed to a foundation via an anti-vibration member (for example, Patent Document 1). Etc.) and an anti-vibration element for reducing vibration transmission to the load between the floor part (corresponding to the lower frame) and the internal floor (corresponding to the upper frame) that constitute the double bottom structure An anti-vibration container (see, for example, Patent Document 2) is known.

  Further, as another anti-vibration stand, an anti-vibration pallet for transporting a load by a forklift or the like is also known (see, for example, Patent Document 3). The anti-vibration pallet has a structure in which, for example, an upper frame and a lower frame formed in a lattice shape or a frame shape are arranged to face each other with an anti-vibration element interposed therebetween. The lower frame is usually formed in the same size and shape as the upper frame. In addition, a predetermined gap is provided between the upper base and the lower base.

  The lower platform is installed on the floor, while the load is placed on the upper platform. A fork such as a forklift is inserted into the gap, and the load on the anti-vibration pallet is moved by moving the fork while being lifted together with the anti-vibration pallet.

  A plurality of anti-vibration mounts on which the outdoor units and the like are loaded are usually installed side by side in an outdoor unit storage area such as a rooftop of a building. Also, a plurality of anti-vibration pallets are accommodated side by side inside the truck bed or container. The plurality of vibration isolation mounts are arranged as close to each other as possible from the viewpoint of efficient use of the arrangement space.

  However, the outdoor unit etc. on the anti-vibration stand may be greatly shaken by strong winds, earthquakes, etc., and there is a possibility that adjacent outdoor units etc. collide with each other. Also, the loads on the anti-vibration pallet may be greatly shaken during transportation by a truck and collide with each other.

Therefore, in general, as shown in FIG. 9, a predetermined interval is secured between the anti-vibration pallets 101 by interposing a wooden bar 102 or the like between the adjacent anti-vibration pallets 101. It has been broken. In addition, a cushioning material 104 such as an air mat or sponge material is provided between the adjacent loads 103.
JP 2004-324656 A JP 2004-292026 A JP 2005-147277 A

  However, in such a conventional method, there is a problem that a separate member is required in addition to the anti-vibration mount for the purpose of preventing a collision between the loads. In addition, since it takes time to install such another member, there is also a problem that it takes time to install the anti-vibration mount and its load.

  Furthermore, when the square bar is too small, the loaded items collide with each other regardless of the intervention of the square bar. On the other hand, when the square bar is too large, the collision between the loads is prevented, but the interval between the loads becomes large, so that the arrangement space cannot be effectively used.

  The present invention has been made in view of such various points, and the main object of the present invention is to prevent a collision between loads without using a separate member, and to effectively use an arrangement space for a vibration isolator. The purpose is to use it.

  In order to achieve the above object, according to the present invention, the lower pedestal is projected outward in the horizontal direction from the upper pedestal, and the projecting width is defined within a predetermined range.

Specifically, the vibration isolator according to the first aspect of the present invention includes a rectangular upper base on which a load is placed, a lower base disposed below the upper base and facing the upper base, and the upper base. A plurality of anti-vibration elements interposed between the base and the lower base, for reducing vibration transmission to the load, and between the upper base and the lower base, and the upper base with respect to the lower base A vibration isolator with a stopper for restricting relative movement in the horizontal direction and the vertical direction, wherein the stopper is arranged along a side of the upper base, and the lower base is the upper base The protrusion width W of the protrusion has a maximum movement width in the vertical direction of the upper base restricted by the stopper as h1 and a maximum movement width in the horizontal direction. Is W2, the height of the load is H, When the distance of the stopper with each other are arranged on both end sides of the side and is P,
H × h1 / P + W2 <W <1.5 × (H × h1 / P + W2) (1)
The following relational expression is established.

  According to this configuration, the load placed on the upper pedestal has the vibration isolation element interposed between the load and the lower pedestal, so that vibration transmission to the load is reduced. When the upper base is greatly shaken, the relative movement with respect to the lower base becomes large. The relative movement of the upper base is regulated by a stopper. In other words, the upper base moves relatively between the limit positions in the vertical direction, and relatively moves between the limit positions in the horizontal direction.

  By the way, when a plurality of anti-vibration mounts are arranged close to each other, a collision between loads on each anti-vibration stand becomes a problem. The vibration isolator of the present invention is configured such that the movement of the load is restricted by the stopper, and the horizontal movement range of the upper end of the load in particular is not overlapped between adjacent loads. Yes.

  That is, when one of the stoppers arranged on both ends of the side of the upper frame regulates the upper frame at the upper limit position and the other stopper regulates the upper frame at the lower limit position, The object is most inclined and its upper end moves in the horizontal direction by the maximum movement width W1. Furthermore, the horizontal movement of the load is allowed only by the maximum movement width W2 by the stopper itself. Therefore, the upper end of the load moves in total by a maximum of W1 + W2.

  Here, as shown in FIG. 7, assuming that the maximum inclination of the load is θ, tan θ = h1 / P (h1 is the maximum movement width in the vertical direction of the upper base, and P is the interval between the stoppers). . Furthermore, since tan θ≈W1 / H (H is the height of the load), W1 = H × h1 / P approximately.

  Therefore, in the present invention, the lower pedestal is protruded in advance from the upper pedestal, and the protruding width W is set to the maximum horizontal movement width W1 + W2 = H × h1 / of the upper end of the load as shown in the above equation (1). Since it is defined to be larger than P + W2, collision between adjacent loads can be prevented in advance. On the other hand, since the protrusion width W of the lower pedestal is defined to be smaller than 1.5 × (H × h1 / P + W2), it is possible to efficiently arrange the anti-vibration gantry and its load in a predetermined arrangement space. It becomes.

In the vibration isolator according to the second invention, the stopper has a shaft portion inserted into an opening formed on the upper frame side or the lower frame side, and the upper frame has moved to a limit position in the horizontal direction. In some cases, the outer peripheral surface of the shaft portion is configured to abut against the inner peripheral surface of the opening portion, and the maximum horizontal movement width W2 of the upper frame is D, where the inner diameter of the opening portion is D. When the outer diameter of M is M,
W2 = (D−M) / 2 (2)
Is defined by the relational expression

  According to this configuration, when the stopper is configured by the shaft portion inserted through the opening, W2 is defined by the above equation (2). Accordingly, the protrusion width W of the undercarriage is more specific as H × h1 / P + (D−M) / 2 <W <1.5 × (H × h1 / P + (D−M) / 2). Will be specified.

  In the vibration isolator according to the third aspect of the present invention, the protruding portion is formed over the entire outer peripheral edge of the lower rack.

  According to this configuration, since the protrusions are formed over the entire outer peripheral edge of the lower frame, each vibration isolation frame is positioned at a predetermined position in order to place the protrusions of adjacent vibration isolation frames in contact with each other. There is no need to arrange them together. As a result, it is possible to easily arrange a plurality of vibration isolation stands in a predetermined arrangement space.

  According to the first aspect of the invention, the lower base is protruded in the horizontal direction from the upper base, and the protruding width is regulated within a predetermined range. In addition, it is possible to effectively use the arrangement space of the vibration isolator.

  According to the second invention, it is possible to specifically specify the protruding width of the undercarriage when the stopper is configured by the shaft portion inserted through the opening.

  According to the third aspect of the present invention, the protruding portions can be arranged to be in contact with each other without aligning the plurality of vibration isolating stands. Therefore, a plurality of vibration isolating stands can be easily arranged in a predetermined arrangement space.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the following embodiment.

  1 to 8 show an embodiment of the present invention. In this embodiment, a vibration isolation pallet according to the present invention will be described using a vibration isolation pallet as an example. FIG. 2 is a plan view showing the appearance of the vibration isolating pallet 10, and FIGS. 3 and 4 are side views of the vibration isolating pallet 10. In the present embodiment, the left-right direction in FIG. 2 is referred to as “left-right direction”, and the up-down direction in FIG. 2 is referred to as “front-rear direction”.

  As shown in FIGS. 2 to 4, the anti-vibration pallet 10 is provided with an upper base 11 on which a load, which is a precision part such as a semiconductor or a liquid crystal panel, is mounted, and a predetermined gap 20 below the upper base 11. And a plurality of anti-vibration elements 13 interposed between the upper platform 11 and the lower platform 12 for reducing fine vibration transmission to the load.

  The upper frame 11 is configured by combining a plurality of general structural square steel pipes (STKR), and is formed in a lattice frame shape. That is, the upper frame 11 includes a rectangular frame portion 15 having a rectangular frame shape, and a set of beam members 16 that are spanned in parallel with one side extending in the front-rear direction of the rectangular frame portion 15 at a substantially central position. And a beam member 17 that extends over the rectangular frame portion 15 on both outer sides of the pair of beam members 16 and extends in parallel with each beam member 16.

  An interval between the beam member 17 and one side of the rectangular frame portion 15 extending in the front-rear direction on the outside thereof is the same as the interval between the pair of beam members 16. In other words, between two opposing sides of the rectangular frame portion 15 extending in the front-rear direction, the beam member 17, the pair of beam members 16, and the beam member 17 are arranged in parallel with each other in this order.

  Furthermore, the upper base 11 has a beam member 18 that extends in the left-right direction and connects the central portions of the adjacent beam members 16 and 17. The rectangular frame portion 15 and the beam members 16, 17, and 18 are configured by a general structural square steel pipe having a rectangular cross section. Further, as shown in FIG. 2 with a part thereof omitted, the upper base 11 has a rectangular top plate 19 attached to the upper surface of the rectangular frame portion 15 and the beam members 16, 17, and 18. is doing. The load is placed on the upper surface of the top plate 19.

  The lower gantry 12 has the same configuration as the upper gantry 11, but is different in that it does not have the top plate 19 and is slightly larger than the upper gantry 11. The lower gantry 12 is disposed below the upper gantry 11 so as to face the upper gantry 11. That is, the lower gantry 12 includes a rectangular frame portion 55 that is slightly larger than the rectangular frame portion 15 of the upper gantry 11, and similarly to the upper gantry 11, a pair of parallel beam members 16, and each beam member 17, 18. The beam members 16, 17, and 18 of the lower gantry 12 are arranged to face the beam members 16, 17, and 18 of the upper gantry 11, respectively.

  The gap 20 is formed between the rectangular frame 15 and the lower surfaces of the beam members 16, 17, and 18 on the upper frame 11 and the upper surfaces of the rectangular frame 55 and the beam members 16, 17 and 18 on the lower frame. It is partitioned. A lift fork such as a forklift is inserted into the gap 20.

  As shown in FIGS. 3 and 4, the rectangular frame portion 15 of the upper frame 11 and the lower surfaces of the beam members 16, 17, 18, and the rectangular frame portion 55 of the lower frame 12 and the beam members 16, 17, 18 A protective member 22 made of a stainless material such as SUS304 is attached to each upper surface. The protective member can be formed of an aluminum material.

  The protection member 22 is formed in a substantially rectangular plate shape. The width of the protection member 22 is substantially the same as the sides of the rectangular frame portions 15 and 55 and the beam members 16, 17 and 18. On the side of the protection member 22, a rectangular frame portions 15 and 55 and a bent portion 23 that is bent along the surfaces of the beam members 16, 17, and 18 are formed. Thus, the protection member 22 is affixed to the upper frame 11 and the lower frame 12 with a double-sided tape.

  As shown in FIG. 2, the anti-vibration elements 13 are disposed at both ends and the center of the pair of beam members 16, and are supported by the beam members 16 and the rectangular frame portion 15. The other anti-vibration elements 13 are disposed at both ends and the center of the beam member 17 and one side of the rectangular frame portion 15 adjacent thereto, and are supported by the beam member 17 and the rectangular frame portion 15.

  As shown in FIG. 5, which is a cross-sectional view of the vibration-proof pallet 10 in an unloaded state, the vibration-proof element 13 has an elastic portion 30 that is elastically deformed between the upper frame 11 and the lower frame 12. The elastic part 30 has a structure in which ring-shaped rubber members 31 and disk-shaped partition plates 32 are alternately arranged and stacked. The rubber member 31 is made of high damping rubber, while the partition plate 32 is made of a metal plate. Each rubber member 31 is fixed to the partition plate 32 by a pin 33.

  Thus, the plurality of rubber members 31 and the plurality of partition plates 32 are alternately connected to constitute the elastic portion 30, and the entire elastic portion 30 is deformed integrally.

  The upper end of the elastic portion 30 is fastened and fixed to the upper base 11 by a bolt 36 via a bracket 35 having a substantially rectangular plate shape. On two opposite sides of the bracket 35, bent portions 35a bent downward are formed. On the other hand, a box-like base portion 37 whose lower portion is opened is fixed to the undercarriage 12. The lower end of the elastic portion 30 is fastened and fixed to the top plate portion 37 a of the base portion 37 by a bolt 38.

  The upper base 11 is provided with an element cover 40 for protecting the vibration isolating element 13. The element cover 40 is formed in a vertically extending rectangular cylinder shape, and the upper end portion of the element cover 40 is attached and fixed to the bent portion 35 a of the bracket 35 in a state of being disposed so as to surround the vibration isolation element 13. Further, the lower end of the element cover 40 is disposed below the lower end of the elastic portion 30 in an unloaded state.

  As shown in FIG. 2, the anti-vibration element 13 disposed at the center position of the upper base 11 in a plan view and the anti-vibration elements 13 disposed on both outer sides via the beam member 18 include 2 Two elastic portions 30 are provided. The other anti-vibration elements 13 (that is, the anti-vibration elements 13 disposed at both ends of the beam member 16 and the anti-vibration elements 13 disposed at both ends of the beam member 17) include two elastic portions. 30 and a stopper 41 are provided.

  A plurality of stoppers 41 are provided between the upper gantry 11 and the lower gantry 12, and are configured to restrict horizontal movement and vertical movement of the upper gantry 11 with respect to the lower gantry 12. The stoppers 41 are arranged so as to be aligned along the left and right sides and the front and rear sides of the upper base 11 in plan view (that is, the sides of the rectangular frame portions 15 and 55).

  As shown in FIG. 5, the stopper 41 is disposed between the two elastic portions 30, and extends vertically through the ring-shaped upper stopper body 42 and the lower stopper body 43, and the stopper bodies 42 and 43. And an extending shaft portion 44.

  The upper end portion of the shaft portion 44 is fastened and fixed to the upper base 11 via the bracket 35. On the other hand, the lower end portion of the shaft portion 44 is inserted into an opening portion 37 b formed in the top plate portion 37 a of the base portion 37 and extends into the lower base portion 37. The stopper body 43 is fastened and fixed.

  The upper stopper body 42 is fastened and fixed to the shaft portion 44 in a state where the upper stopper body 42 is disposed above the lower stopper body 43 by a predetermined height. For example, three bolts 45 are provided on the shaft portion 44 between the upper stopper main body 42 and the bracket 35. By increasing or decreasing the number of the bolts 45, the distance between the upper stopper body 42 and the lower stopper body 43 is adjusted. In addition, ring-shaped rubber portions 46 are provided at the lower part of the upper stopper body 42 and the upper part of the lower stopper body 43, respectively.

  The inner diameter D of the opening 37 b in the base portion 37 is smaller than the outer diameter of each rubber portion 46 of the upper stopper main body 42 and the lower stopper main body 43. Then, when the load is placed on the upper stand 11, the upper stand 11 moves downward according to the weight of the load, as shown in FIG. When the upper base 11 is further lowered and moved to the lower limit position, the upper surface of the top plate portion 37a around the opening 37b comes into contact with the lower surface of the rubber portion 46 of the upper stopper body 42. On the other hand, when the upper base 11 is raised and moved to the upper limit position, the lower surface of the top plate portion 37 a around the opening 37 b comes into contact with the upper surface of the rubber portion 46 of the lower stopper main body 43. Thus, the vertical movement width of the upper base 11 is regulated by the stopper 41.

  Further, as shown in FIG. 8 which is a sectional view, the outer diameter M of the shaft portion 44 is smaller than the inner diameter D of the opening portion 37b. A predetermined interval W2 is provided between the outer peripheral surface of the shaft portion 44 and the inner peripheral surface of the opening portion 37b in a state where the axial center of the shaft portion 44 and the center of the opening portion 37b coincide. When the upper base 11 moves to the limit position on the outer side in the horizontal direction, the outer peripheral surface of the shaft portion 44 comes into contact with the inner peripheral surface of the opening portion 37b. In this way, the horizontal movement width of the upper base 11 is also regulated by the stopper 41.

  The stopper 41 has a shaft portion inserted into the opening 37b formed on the lower frame 12 side. In addition, the stopper 41 is configured to be inserted into the opening formed on the upper frame 11 side. It is good.

  As a feature of the present invention, as shown in FIG. 2 to FIG. 6, the lower pedestal 12 has protrusions 55 a and 55 b that protrude outward in the horizontal direction along the side of the upper pedestal 11 rather than the upper pedestal 11. ing. As shown in FIG. 2, the protruding portion 55 a protrudes outward in the left-right direction from the upper base 11, while the protruding portion 55 b protrudes outward in the front-rear direction from the upper base 11. Thus, as a result of the protrusions 55a and 55b being formed over the entire outer peripheral edge of the lower frame 12, the lower frame 12 is larger than the upper frame 11 as a whole.

Here, as shown in FIG. 7 which is a schematic diagram showing the inclination and the movement range of the load 60, the maximum movement width in the vertical direction of the upper base 11 regulated by the stopper 41 is set to h1 and the maximum movement in the horizontal direction. The width is W2. Further, the height of the load 60 is set to H, and the interval between the stoppers 41 disposed on both ends in the left-right direction of the side of the upper base 11 is set to P. At this time, the protruding width W in the left-right direction of the protruding portion 55a is
H × h1 / P + W2 <W <1.5 × (H × h1 / P + W2) (1)
The following relational expression is established.

Furthermore, as shown in FIG. 8, the maximum horizontal movement width W2 is larger than the inner diameter D of the opening portion 37b and the outer diameter M of the shaft portion 44.
W2 = (D−M) / 2 (2)
Is defined by the relational expression

Therefore, according to the above formulas (1) and (2), the protruding width W in the left-right direction of the protruding portion 55a is
H × h1 / P + (D−M) / 2 <W <1.5 × (H × h1 / P + (D−M) / 2)
... (3)
As more specifically defined.

On the other hand, with respect to the protrusion width w in the front-rear direction of the protrusion 55b, if the interval between the stoppers 41 disposed on both ends in the front-rear direction of the side of the upper base 11 is p,
H × h1 / p + W2 ≦ w ≦ 1.5 × (H × h1 / p + W2) (4)
The following relational expression is established. Furthermore, since the maximum movement width W2 is defined by the above formula (2), the protrusion width w in the front-rear direction of the protrusion 55b is
H × h1 / p + (D−M) / 2 <w <1.5 × (H × h1 / p + (D−M) / 2)
···(Five)
It is prescribed as

  For example, when cargo such as precision parts is transported by a truck or container, the cargo is loaded as a load on the plurality of anti-vibration pallets 10 and accommodated in the truck bed or inside the container. .

  Here, when the load is placed on the top plate 19 of the gantry 11, the elastic portion 30 of the vibration isolation element 13 is compressed, and the gantry 11 is moved from the unloaded state shown in FIG. Move down as shown. Subsequently, a lift fork such as a forklift is lifted in a state where it is horizontally inserted into the gap 20 of the vibration isolating pallet 10. As a result, the load is lifted by the lift fork and is transported together with the anti-vibration pallet 10 to a truck bed or the like.

  As shown in FIG. 1, each anti-vibration pallet 10 is arranged on a truck bed or the like so that the projecting portions 55 a or the projecting portions 55 b of the lower mounts 12 are abutted against each other and come into contact with each other. Since the anti-vibration pallet 10 has the anti-vibration element 13 interposed between the upper base 11 and the lower base 12, fine vibration transmission to a load such as a precision part is reduced.

-Effect of the embodiment-
By the way, when a large shake is applied to the lower gantry 12, the relative movement of the upper gantry 11 with respect to the lower gantry 12 also increases, but the relative movement of the upper gantry 11 is restricted by the stopper 41. That is, the upper base 11 relatively moves within the range between the limit positions in the vertical direction, and relatively moves within the range between the limit positions in the horizontal direction.

  First, a case where the load 60 is relatively moved in the left-right direction will be described. As shown in FIG. 7, one of the stoppers 41 arranged on both ends of the side of the upper base 11 regulates the upper base 11 at the upper limit position, and the other stopper 41 lowers the upper base 11. When the limit position is regulated, the load 60 is most inclined and the upper end thereof moves in the horizontal direction by the maximum movement width W1. Further, the horizontal movement of the load 60 is allowed by the stopper 41 itself by the maximum movement width W2. Accordingly, the upper end of the load 60 moves by a maximum of W1 + W2 in total.

  Here, when the maximum inclination of the load 60 is θ, tan θ = h1 / P. Furthermore, since tan θ≈W1 / H, approximately W1 = H × h1 / P. Therefore, in the present embodiment, the protrusions 55a are provided on the lower base 12 so that the lower base 12 protrudes in the left and right sides from the upper base 11 in advance, and the protrusion width W is expressed by the above formula (1) and the formula As shown in (2), since the maximum horizontal movement width W1 + W2 = H × h1 / P + W2 (= H × h1 / P + (D−M) / 2) of the upper end of the load is specified, the collision This makes it possible to prevent the left and right horizontal movement ranges of the upper end of the load 60 from overlapping with each other. As a result, a collision in the left-right direction between the adjacent loads 60 can be prevented in advance.

  Next, a case where the load 60 is relatively moved in the front-rear direction will be described. In this case, it can be defined in the same manner as in the case of the movement in the left-right direction. That is, the upper end of the load 60 moves by a total w1 + W2 of the maximum movement width w1 due to the inclination and the maximum movement width W2 due to the stopper 41 itself. On the other hand, in the present embodiment, the projecting portion 55b is provided on the undercarriage 12, and the projecting width w is set at the front and rear of the upper end of the load 60 as in the above formulas (4) and (5). Since the maximum movement width w1 + W2 = H × h1 / p + W2 (= H × h1 / p + (D−M) / 2) is defined, the adjacent loads 60 are similar to each other in the left-right direction. It is possible to prevent a collision in the front-rear direction.

  On the other hand, the width W of the lower base 12 is defined to be smaller than 1.5 × (H × h1 / P + W2), and the width w of protrusion in the front-rear direction is 1.5 × (H × h1 / p + W2). Therefore, the anti-vibration pallet 10 and its load 60 can be efficiently arranged and arranged in a limited arrangement space such as a truck bed. As a result, it is possible to reduce the vibration transmission to the load 60 and improve the transport reliability, and to efficiently transport a plurality of load 60 at a time and reduce the cost required for the transport.

  In addition, it is more preferable to define the protruding width W in the left-right direction of the undercarriage 12 to be smaller than 1.2 × (H × h1 / P + W2). Moreover, it is preferable to define the protrusion width w in the front-rear direction to be smaller than 1.2 × (H × h1 / p + W2). As a result, it is possible to arrange more loads 60 in a predetermined arrangement space and transport the loads 60 more efficiently. That is, it is possible to effectively use a limited arrangement space.

  In addition to this, in the present embodiment, a separate member other than the anti-vibration pallet 10 is not required for the purpose of preventing a collision between the loads 60. Therefore, the trouble of installing such another member becomes unnecessary. The installation work of the anti-vibration pallet 10 and its load 60 can be easily performed.

  Further, since the protrusions 55a and 55b are formed over the entire outer peripheral edge of the undercarriage 12, each of the anti-vibration pallets 10 is arranged so that the protrusions 55a and the protrusions 55b face each other. There is no need to position the swing pallet 10 in a predetermined position. As a result, the plurality of vibration isolation pallets 10 can be easily arranged in a predetermined arrangement space.

<< Other Embodiments >>
The configuration of the present invention is not limited to the above embodiment, but includes various other configurations. That is, in the said embodiment, although the vibration proof pallet 10 was mentioned and demonstrated as an example of the vibration proof stand based on this invention, this invention is not limited to this. That is, for example, the present invention can be similarly applied to other anti-vibration frames such as an anti-vibration frame that supports an outdoor unit of an air conditioner or a vibration-proof container that accommodates a load.

  Moreover, in the said embodiment, although protrusion part 55a, 55b was provided over the whole outer periphery of the undercarriage 12, this invention is not limited to this. That is, a protrusion may be formed on a part of the outer peripheral edge of the undercarriage 12. Then, by arranging the protruding portions of the adjacent anti-vibration pallets so as to face each other, the load on each anti-vibration pallet is prevented from colliding with each other while eliminating the need for another member, as in the first embodiment. Can do.

  As described above, the present invention is useful for an anti-vibration pallet that reduces vibration transmission to a load such as a precision instrument, and in particular, prevents collision between loads without using a separate member. At the same time, it is suitable for the effective use of the arrangement space of the vibration isolation frame.

It is a side view which shows two adjacent anti-vibration pallets and its load. It is a top view which shows the external appearance of a vibration proof pallet. It is a side view which shows the external appearance of a vibration proof pallet. It is a side view which shows the external appearance of a vibration proof pallet. It is sectional drawing which expands and shows the vibration isolator of a no-load state. It is sectional drawing which expands and shows the vibration isolator of a load loading state. It is a schematic diagram which shows the inclination and moving range of a load. It is sectional drawing which shows the axial part of the stopper penetrated by the opening part. It is a side view which shows two conventional anti-vibration pallets and their load.

Explanation of symbols

D Opening inner diameter M Shaft outer diameter W2 Horizontal maximum travel width h1 Vertical maximum travel width H Load height P Space between stoppers W Protrusion projection width 10 Anti-vibration pallet (anti-vibration stand) )
DESCRIPTION OF SYMBOLS 11 Upper mount 12 Lower mount 13 Anti-vibration element 37b Opening part 41 Stopper 44 Shaft part 55a, 55b Protrusion part 60 Loaded object

Claims (3)

A rectangular platform on which the load is placed;
A lower base disposed below the upper base and facing the upper base;
An anti-vibration element interposed between the upper frame and the lower frame, for reducing vibration transmission to the load;
A vibration isolating base provided with a stopper provided between the upper base and the lower base, and a stopper for restricting relative movement in the horizontal direction and the vertical direction of the upper base with respect to the lower base;
The stopper is arranged so as to be aligned along the side of the upper base,
The lower mount has a protruding portion that protrudes outward in the horizontal direction from the upper mount,
The projecting width W of the projecting portion is set to h1 as the maximum vertical movement width of the upper base restricted by the stopper, and W2 as the maximum horizontal movement width, and the height of the load is H. When the interval between the stoppers arranged on both ends of the side of the above-described upper frame is P,
H × h1 / P + W2 <W <1.5 × (H × h1 / P + W2)
An anti-vibration stand that is defined such that the following relational expression holds. In claim 1,
The stopper has a shaft portion inserted through an opening formed on the upper frame side or the lower frame side, and when the upper frame moves to a horizontal limit position, the outer peripheral surface of the shaft portion is Configured to contact the inner peripheral surface of the opening,
The maximum horizontal movement width W2 of the upper pedestal is such that when the inner diameter of the opening is D and the outer diameter of the shaft is M,
W2 = (D−M) / 2
An anti-vibration stand characterized by the following relational expression. In claim 1,
The anti-vibration mount is characterized in that the protrusion is formed over the entire outer periphery of the lower mount.

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