CN216505036U - Adjustable stacking frame for hospital construction - Google Patents

Abstract

The utility model relates to the technical field of stacking frames, in particular to an adjustable stacking frame for hospital construction. A stacking frame with adjustable be used for hospital's construction includes base, bottom windrow subassembly, top layer windrow mechanism and control mechanism, a plurality of spout has been seted up on the base, bottom windrow subassembly erects on the base, bottom windrow subassembly includes pi shaped plate, pi shaped plate of second and expansion plate, pi shaped plate of first pi shaped plate and second all erects on the base, and through expansion plate telescopic connection between pi shaped plate of first pi shaped plate and the pi shaped plate of second, top layer windrow frame establishes on the base for control windrow area control mechanism installs on the base. The adjustable stacking rack for hospital construction provided by the utility model can adjust the stacking area and has the advantages of time saving and labor saving.

Description

Adjustable stacking frame for hospital construction

Technical Field

The utility model relates to the technical field of stacking frames, in particular to an adjustable stacking frame for hospital construction.

Background

When carrying out interior decoration, the material is more, need use the stacker to put it in good order, avoids taking too much space, the drive of being convenient for, and current stacker when using, can not adjust its stacker area, when stacking less material, occupies too much area, causes crowdedly, when idle moreover, the area that occupies is too big, is unfavorable for accomodating.

Therefore, there is a need to provide a new adjustable stacker for hospital construction to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides the adjustable stacking rack which can adjust the stacking area, is time-saving and labor-saving and is used for hospital construction.

The utility model provides an adjustable stacking rack for hospital construction, which comprises:

the base is provided with a plurality of sliding grooves;

the bottom layer stacking assembly is erected on the base and comprises a first pi-shaped plate, a second pi-shaped plate and a telescopic plate, the first pi-shaped plate and the second pi-shaped plate are erected on the base, and the first pi-shaped plate and the second pi-shaped plate are in telescopic connection through the telescopic plate;

the top layer stacker is constructed on the base;

and the control mechanism is used for controlling the stacking area and is arranged on the base.

Preferably, both ends of the first pi-shaped plate are fixedly provided with first supporting rods, the first supporting rods are inserted into the sliding grooves and are in sliding connection with the inner side walls of the sliding grooves, both ends of the second pi-shaped plate are fixedly provided with second supporting rods, and the second supporting rods are inserted into the sliding grooves and are in sliding connection with the inner side walls of the sliding grooves.

Preferably, top layer windrow mechanism includes first telescopic link, first backup pad, recess, first windrow board, breach, second windrow board, second telescopic link and second backup pad, two the one end fixed mounting of first telescopic link has first backup pad, and first backup pad insert establish on the base set up the recess in and with recess sliding connection, two the other end of first telescopic link all passes first wu jian board and fixed mounting on first windrow board, set up the breach on the first windrow board, and insert the second windrow board that is equipped with sliding connection in the breach, the equal fixed mounting in both ends of second windrow board has the second telescopic link, and fixed mounting has the second backup pad on the second telescopic link, the second backup pad insert establish on the base in the recess seted up and with recess sliding connection.

Preferably, install elevating system on the top layer windrow mechanism, elevating system includes lead screw, crank, thread bush and dwang, the both ends of lead screw are all installed on first telescopic link and are rotated with first telescopic link and be connected, and the one end fixed mounting of lead screw has the crank, threaded connection's thread bush has all been cup jointed at the both ends of lead screw, and installs the dwang of rotating the connection on the thread bush, the dwang is installed on first stacking plate and is rotated with first stacking plate and be connected.

Preferably, control mechanism is including rotating motor, first threaded rod, first belt pulley, second threaded rod, second belt pulley and belt, rotate motor fixed mounting on the base, and fixed mounting has first threaded rod on the output shaft of rotation motor, first threaded rod passes spout and fixed mounting has first belt pulley, the one end of second threaded rod is rotated with the inside wall of spout and is connected, and the other end of second threaded rod passes spout and fixed mounting has the second belt pulley, the second belt pulley passes through the belt and is connected with first belt pulley transmission.

Preferably, the first threaded rod is in threaded connection with the inserting end of the first support rod, and the second threaded rod is in threaded connection with the inserting end of the second support rod.

Preferably, the bottom of the second stacking plate is fixedly provided with a connecting plate, and the connecting plate is inserted into a through groove formed in the first stacking plate and is in sliding connection with the through groove.

Preferably, a locking rod connected with threads is inserted on the first telescopic rod.

Compared with the related art, the adjustable stacking rack for hospital construction provided by the utility model has the following beneficial effects:

1. the utility model provides an adjustable stacking rack for hospital construction, during stacking, a control mechanism is used for adjusting the stacking area of a bottom stacking component and a top stacking mechanism according to the volume of materials, then the materials are classified, the larger material is preferentially placed on the bottom stacking component, the smaller material which easily falls is placed on the top stacking mechanism, and during storage, the control mechanism is used for reducing the stacking area, so that the occupied storage area is reduced, and the storage is convenient;

2. when carrying out the eminence construction, use elevating system to adjust the height of first stacking plate and second stacking plate, place the material that needs on first stacking plate and second stacking plate and be convenient for take.

Drawings

FIG. 1 is a schematic structural view of an adjustable stacker for hospital construction according to a preferred embodiment of the present invention;

FIG. 2 is a rear view of the structure of FIG. 1;

fig. 3 is a schematic bottom view of the structure shown in fig. 1.

Reference numbers in the figures: 1. a base; 2. a chute; 3. a bottom layer stacking assembly; 31. a first Pi-shaped plate; 32. a second pi-shaped plate; 33. a retractable plate; 4. a first support bar; 5. a second support bar; 6. a top layer stacking mechanism; 61. a first telescopic rod; 62. a first support plate; 63. a groove; 64. a first stacking plate; 65. a notch; 66. a second material piling plate; 67. a second telescopic rod; 68. a second support plate; 7. a lifting mechanism; 71. a screw rod; 72. a crank; 73. a threaded sleeve; 74. rotating the rod; 8. a control mechanism; 81. rotating the motor; 82. a first threaded rod; 83. a first pulley; 84. a second threaded rod; 85. a second pulley; 86. a belt; 9. a connecting plate; 9a, a through groove; 9b, locking lever.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

Referring to fig. 1 to 3, an embodiment of the present invention provides an adjustable stacker for hospital construction, where the adjustable stacker for hospital construction includes:

the device comprises a base 1, wherein a plurality of sliding grooves 2 are formed in the base 1;

the bottom layer stacking assembly 3 is erected on the base 1, the bottom layer stacking assembly 3 comprises a first pi-shaped plate 31, a second pi-shaped plate 32 and a telescopic plate 33, the first pi-shaped plate 31 and the second pi-shaped plate 32 are both erected on the base 1, and the first pi-shaped plate 31 and the second pi-shaped plate 32 are in telescopic connection through the telescopic plate 33;

the top layer stacking mechanism 6 is erected on the base 1;

and the control mechanism 8 is used for controlling the stacking area, and the control mechanism 8 is arranged on the base 1.

It should be noted that: during stacking, the control mechanism 8 is used for adjusting the stacking areas of the bottom stacking component 3 and the top stacking mechanism 6 according to the volume of the materials, then the materials are classified, the larger material is preferentially placed on the bottom stacking component 3, the smaller material which easily falls is placed on the top stacking mechanism 6, and during storage, the control mechanism 8 is used for reducing the stacking area, so that the occupied storage area is reduced, and the storage is convenient; when the high-altitude construction is carried out, the required materials are placed on the top layer stacking mechanism 6 to be convenient to take and use.

In the embodiment of the present invention, please refer to fig. 1 and 2, two ends of the first pi-shaped plate 31 are both fixedly installed with a first support rod 4, and the first support rod 4 is inserted into the sliding slot 2 and is slidably connected with the inner side wall of the sliding slot 2, two ends of the second pi-shaped plate 32 are both fixedly installed with a second support rod 5, and the second support rod 5 is inserted into the sliding slot 2 and is slidably connected with the inner side wall of the sliding slot 2; the control mechanism 8 comprises a rotating motor 81, a first threaded rod 82, a first belt pulley 83, a second threaded rod 84, a second belt pulley 85 and a belt 86, the rotating motor 81 is fixedly mounted on the base 1, the first threaded rod 82 is fixedly mounted on an output shaft of the rotating motor 81, the first threaded rod 82 penetrates through the sliding chute 2 and is fixedly mounted with the first belt pulley 83, one end of the second threaded rod 84 is rotatably connected with the inner side wall of the sliding chute 2, the other end of the second threaded rod 84 penetrates through the sliding chute 2 and is fixedly mounted with the second belt pulley 85, and the second belt pulley 85 is in transmission connection with the first belt pulley 83 through the belt 86; the first threaded rod 82 is in threaded connection with the inserting end of the first support rod 4, and the second threaded rod 84 is in threaded connection with the inserting end of the second support rod 5;

it should be noted that: when the stacking area is increased, the rotating motor 81 is started to drive the first threaded rod 82 to rotate, so that the first supporting rod 4 slides in the sliding groove 2, meanwhile, the first belt pulley 83 can drive the second belt pulley 85 to rotate, so that the second threaded rod 84 rotates, the second supporting rod 5 slides in the sliding groove 2, the sliding directions of the first supporting rod 4 and the second supporting rod 5 are opposite, the first pi-shaped plate 31 and the second pi-shaped plate 32 are driven to move in opposite directions, and the stacking area is increased.

In an embodiment of the present invention, referring to fig. 1, fig. 2 and fig. 3, the top layer stacking mechanism 6 includes a first telescopic rod 61, a first supporting plate 62, a groove 63, a first stacking plate 64, a gap 65, a second stacking plate 66, a second telescopic rod 67 and a second supporting plate 68, the first supporting plate 62 is fixedly mounted at one end of the two first telescopic rods 61, the first supporting plate 62 is inserted into a groove 63 formed on the base 1 and is slidably connected with the groove 63, the other ends of the two first telescopic rods 61 penetrate through the first pi-shaped plate 31 and are fixedly mounted on a first material stacking plate 64, the first material stacking plate 64 is provided with a notch 65, a second material piling plate 66 which is connected in a sliding way is inserted in the gap 65, both ends of the second material piling plate 66 are fixedly provided with a second telescopic rod 67, a second supporting plate 68 is fixedly arranged on the second expansion link 67, and the second supporting plate 68 is inserted into a groove 63 formed in the base 1 and is in sliding connection with the groove 63;

it should be noted that: when the first pi-shaped plate 31 and the second pi-shaped plate 32 move in opposite directions, the first telescopic rod 61 and the second telescopic rod 67 are driven to move in opposite directions, and meanwhile, the first supporting plate 62 and the second supporting plate 68 slide in opposite directions in the groove 63, but cannot be completely separated from the groove 63, so that support is provided for the first telescopic rod 61 and the second telescopic rod 67, the first supporting rod 4 and the second supporting rod 5 are prevented from being broken by pressing, and the first material stacking plate 64 and the second material stacking plate 66 can also move in opposite directions, so that the material stacking area is increased;

in this embodiment: the bottom fixed mounting of second flitch 66 has connecting plate 9, and connecting plate 9 inserts and establishes in the logical groove 9a of seting up on first flitch 64 and with logical groove 9a sliding connection, connecting plate 9 links together first flitch 64 and second flitch 66, avoids first flitch 64 and second flitch 66 to lead to the fact first telescopic link 61 and second telescopic link 67 to bend to both sides because of the skew center of the material of piling up, reduction of service life.

In an embodiment of the present invention, referring to fig. 1, a lifting mechanism 7 is installed on the top-layer stacking mechanism 6, the lifting mechanism 7 includes a screw rod 71, a crank 72, a threaded sleeve 73 and a rotating rod 74, both ends of the screw rod 71 are installed on the first telescopic rod 61 and rotatably connected with the first telescopic rod 61, one end of the screw rod 71 is fixedly installed with the crank 72, both ends of the screw rod 71 are sleeved with the threaded sleeve 73 in threaded connection, the threaded sleeve 73 is installed with the rotating rod 74 in rotatable connection, and the rotating rod 74 is installed on the first stacking plate 64 and rotatably connected with the first stacking plate 64;

it should be noted that: during high-altitude construction, the crank 72 is shaken to drive the screw rod 71 to rotate, so that the threaded sleeve 73 moves on the screw rod 71, the rotating rod 74 is driven to elongate or shorten the first telescopic rod 61 and the second telescopic rod 67, the heights of the first material stacking plate 64 and the second material stacking plate 66 are changed, and workers can take materials conveniently;

in the present embodiment: the first telescopic rod 61 is inserted with a locking rod 9b in threaded connection, and after the height is adjusted, the locking rod 9b is screwed down, so that the situation that the screw rod 71 is bent due to the fact that the whole weight is applied to the screw rod 71 is avoided.

The working principle of the adjustable stacking rack for hospital construction provided by the utility model is as follows:

when stacking materials, according to the volume of the materials, the control mechanism 8 is used to adjust the stacking area of the bottom layer stacking component 3 and the top layer stacking mechanism 6, and when the stacking area is increased, the rotating motor 81 is started to drive the first threaded rod 82 to rotate, so that the first supporting rod 4 slides in the sliding groove 2, and simultaneously the first belt pulley 83 drives the second belt pulley 85 to rotate, so that the second threaded rod 84 rotates, so that the second supporting rod 5 slides in the sliding groove 2, the sliding directions of the first supporting rod 4 and the second supporting rod 5 are opposite, the first pi-shaped plate 31 and the second pi-shaped plate 32 are driven to move in opposite directions, the stacking area is increased, as the first pi-shaped plate 31 and the second pi-shaped plate 32 move in opposite directions, the first telescopic rod 61 and the second telescopic rod 67 are driven to move in opposite directions, and simultaneously the first supporting plate 62 and the second supporting plate 68 slide in opposite directions in the groove 63, but the material can not be completely separated from the groove 63, the first telescopic rod 61 and the second telescopic rod 67 are supported, the first supporting rod 4 and the second supporting rod 5 are prevented from being broken by pressing, the first material stacking plate 64 and the second material stacking plate 66 can also move in opposite directions, so that the material stacking area is increased, otherwise, the rotating motor 81 is controlled to rotate reversely, the materials are classified, the larger material is preferentially placed on the bottom material stacking component 3, the small material which easily falls is placed on the top material stacking mechanism 6, and when the material is stored, the control mechanism 8 is used for reducing the material stacking area, so that the storage occupied area is reduced, and the storage is convenient; when the high-altitude construction is carried out, the crank 72 is shaken to drive the screw rod 71 to rotate, so that the thread sleeve 73 moves on the screw rod 71, the rotating rod 74 is enabled to elongate or shorten the first telescopic rod 61 and the second telescopic rod 67, the heights of the first material stacking plate 64 and the second material stacking plate 66 are changed, and the worker can take materials conveniently.

The circuits and controls involved in the present invention are prior art and will not be described in detail herein.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. An adjustable stacker for hospital construction, comprising:

the device comprises a base (1), wherein a plurality of sliding grooves (2) are formed in the base (1);

the bottom layer stacking component (3) is erected on the base (1), the bottom layer stacking component (3) comprises a first pi-shaped plate (31), a second pi-shaped plate (32) and a telescopic plate (33), the first pi-shaped plate (31) and the second pi-shaped plate (32) are both erected on the base (1), and the first pi-shaped plate (31) and the second pi-shaped plate (32) are in telescopic connection through the telescopic plate (33);

the top layer stacking mechanism (6), the top layer stacking mechanism (6) is erected on the base (1);

and the control mechanism (8) is used for controlling the stacking area, and the control mechanism (8) is arranged on the base (1).

2. The adjustable stacker for hospital construction according to claim 1, characterized in that both ends of said first pi-shaped plate (31) are fixedly mounted with a first support rod (4), and the first support rod (4) is inserted in the chute (2) and is slidably connected with the inside wall of the chute (2), both ends of said second pi-shaped plate (32) are fixedly mounted with a second support rod (5), and said second support rod (5) is inserted in the chute (2) and is slidably connected with the inside wall of the chute (2).

3. The adjustable stacking rack for hospital construction according to claim 1, characterized in that the top stacking mechanism (6) comprises a first telescopic rod (61), a first supporting plate (62), a groove (63), a first stacking plate (64), a gap (65), a second stacking plate (66), a second telescopic rod (67) and a second supporting plate (68), wherein the first supporting plate (62) is fixedly installed at one end of the two first telescopic rods (61), the first supporting plate (62) is inserted into the groove (63) formed on the base (1) and is slidably connected with the groove (63), the other ends of the two first telescopic rods (61) both penetrate through the first pi-shaped plate (31) and are fixedly installed on the first stacking plate (64), the first stacking plate (64) is formed with a gap (65), and the slidably connected second stacking plate (66) is inserted into the gap (65), the two ends of the second material piling plate (66) are fixedly provided with second telescopic rods (67), second supporting plates (68) are fixedly arranged on the second telescopic rods (67), and the second supporting plates (68) are inserted into grooves (63) formed in the base (1) and are in sliding connection with the grooves (63).

4. The adjustable stacker for hospital construction according to claim 3, wherein a lifting mechanism (7) is installed on the top stacker mechanism (6), the lifting mechanism (7) comprises a screw rod (71), a crank (72), a threaded sleeve (73) and a rotating rod (74), two ends of the screw rod (71) are installed on the first telescopic rod (61) and are rotationally connected with the first telescopic rod (61), the crank (72) is fixedly installed at one end of the screw rod (71), the threaded sleeve (73) in threaded connection is sleeved at two ends of the screw rod (71), the rotating rod (74) in rotational connection is installed on the threaded sleeve (73), and the rotating rod (74) is installed on the first stacker (64) and is rotationally connected with the first stacker plate (64).

5. The adjustable stacker for hospital construction according to claim 2, the control mechanism (8) comprises a rotating motor (81), a first threaded rod (82), a first belt pulley (83), a second threaded rod (84), a second belt pulley (85) and a belt (86), the rotating motor (81) is fixedly arranged on the base (1), and a first threaded rod (82) is fixedly arranged on an output shaft of the rotating motor (81), the first threaded rod (82) penetrates through the sliding groove (2) and is fixedly provided with a first belt pulley (83), one end of the second threaded rod (84) is rotationally connected with the inner side wall of the sliding chute (2), the other end of the second threaded rod (84) passes through the chute (2) and is fixedly provided with a second belt pulley (85), the second belt pulley (85) is in transmission connection with the first belt pulley (83) through a belt (86).

6. The adjustable stacker for hospital construction according to claim 5, characterized in that said first threaded rod (82) is threaded with the inserted end of the first support bar (4) and said second threaded rod (84) is threaded with the inserted end of the second support bar (5).

7. The adjustable stacker for hospital construction according to claim 3, wherein a connecting plate (9) is fixedly mounted at the bottom of the second stacker plate (66), and the connecting plate (9) is inserted into a through slot (9a) formed in the first stacker plate (64) and is slidably connected with the through slot (9 a).

8. The adjustable stacker for hospital construction according to claim 3, characterized in that a locking rod (9b) in threaded connection is inserted on said first telescopic rod (61).

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