KR101503808B1 - Cabinet of elevating type - Google Patents

Abstract

More particularly, the present invention relates to a technology for simplifying the lifting and lowering structure of a cabinet, minimizing the possibility of occurrence of faults, and also facilitating maintenance.
The present invention relates to a technique capable of preventing the lifting structure of a lifting structure due to a weight load by stably lifting and lowering the storage space compared with the conventional technique.
The present invention also relates to a technique capable of preventing unnecessary enlargement of a product size by preventing an unnecessary space from occurring in relation to a lifting structure.

Description

CABINET OF ELEVATING TYPE

The present invention relates to a storage space used in a kitchen and the like. More particularly, the present invention relates to a technology for simplifying a lifting structure and a stable lifting and lowering operation by allowing the entire storage space to be lifted up and down for convenient storage of stored items.

Generally, a storage room such as a sink is installed in several places in a kitchen such as a home or a restaurant.

Most household kitchens have a cabinet above the washbasin, which is located at a higher point than most other cabinets, considering the distance between the cabin and the water valve.

Therefore, a person with a small height, such as a woman or a child, often uses a chair or the like because the use of the storage space is very inconvenient.

Recently, a technique for solving such a problem has been proposed,

This prior art is a technique in which a storage cabinet can be lifted and lowered while a cabinet is housed in a case.

However, this prior art is a structure in which a storage space is connected to a case through a plurality of links and is drawn and lifted by the rotation of the respective links. Since such a link structure uses a plurality of links, it is difficult to manufacture due to the complicated structure, It has a disadvantage that maintenance is difficult as well as this.

In this case, both the weight of the storage space and the weight of the storage article are inevitably concentrated on the link, and since the link structure is not highly supported due to its structural characteristics, the weight of the storage space There is a problem in that a phenomenon such as a breakage of a connecting portion between the links is easily generated.

In the structure in which a plurality of links are connected to each other, there is a disadvantage in that the power transmission structure generated from the drive motor is complicated.

In addition, as described above, since the cabin ascends and descends, it is difficult to use the cabin because of its large radius of movement, and the weight of the cabin becomes larger.

In addition, since the storage space is moved in the arc shape, a space between the case and the upper surface of the storage space is required to prevent collision with each other. However, the space formed between the cabinet and the case is formed only for the prevention of collision, but has no storage function at all, which leads to a disadvantage that the entire product size becomes unnecessarily large.

In addition, a mounting space for link installation must be secured between both side walls of the cabinet and both side walls of the case, which adversely affects the size of the product.

Korean Patent Publication No. 10-0377118 Japanese Laid-Open Patent Publication No. 1995-303534

The present invention has been proposed in order to solve the problems of the prior art,

Basically, it is intended to provide a lifting type cabinet which can be easily manufactured, minimize the possibility of occurrence of faults, and can be easily maintained even by simplifying the lifting structure of the cabinet compared to the conventional one.

Also, it is intended to provide a lifting type cabinet which can prevent a breakage phenomenon of a lifting structure due to a weight load by making it possible to raise and lower the storage cabinet stably compared with the conventional one.

Also, it is intended to provide a lifting type cabinet that can prevent an unnecessary increase in size of a product by preventing an unnecessary space related to a lifting structure.

To this end,

A case having a front and a bottom opened and an installation space formed therein; a storage enclosure accommodated in the installation space so as to be drawn out and having a storage space therein; a drive motor disposed in the installation space; And a rotary screw rod positioned between the side wall of the cabinet and the side wall of the cabinet and having a rear end connected to the drive motor and rotatable and inclined downward toward the front end, And a movement guide member which is linearly movable along the longitudinal direction of the rotary screw rod when the rotary screw rod is rotated.

The rotary screw rod and the movement guide member may be formed on both side walls of the storage space.

In addition, a guide rail inclined in the same manner as the rotary screw rod is formed on the inner surface of the case, and the movement guide member can be moved along the lengthwise direction of the guide rail while being inserted into the guide rail.

A support rail may be formed on one of the inner surface of the case and the sidewall of the cabinet, inclined in the same manner as the rotary screw, and is connected to the other side of the inner surface of the case and the side wall of the cabinet And a support member inserted into the support rail and movable along the longitudinal direction of the support rail.

The driving motor may further include a power transmission unit connected to any one of the rotary rods and connecting the other rotary rods located opposite to the corresponding rotary rods and transmitting rotation force of the rotary rods to the other rotary rods .

Further, another reinforcing frame may be further provided on at least one of the inner and outer circumferential surfaces of the case to prevent the case from being warped.

The present invention having these various embodiments,

Since the cabinet is lifted in the linear direction along the length direction of the rotary screw rod together with the movement guide member when the rotary screw rod is rotated, the lifting structure of the cabinet is simplified compared to the conventional structure, thereby facilitating the production and minimizing the possibility of failure. It has the advantage of being easy.

In addition, since the rotary screw rod and the movement guide member are simultaneously operated in a state where they are positioned on both sides of the storage space, the storage space can be stably lifted and lowered.

In addition, since the moving member is moved together with the storage space in a state where the moving member is inserted into the guide rail of the case, the moving member and the guide rail support the weight of the storage space.

Further, since the support rail and the supporting member connected thereto are further installed, the supporting effect of the cabinet during the ascending and descending movement of the cabinet can be further enhanced.

In addition, since the driving motor is connected to only one of the two rotating or twisted rods, and the rotational force of the rotating screw is transmitted to the opposite rotating tweezers through the power transmitting portion, the economical effect of installing the driving motor can be obtained and the space consumption can be minimized .

In addition, since the rotation speed of the two rotating screw rods is the same, the deviation of the driving force of both sides is prevented during the ascending and descending of the storage cabin, so that it is possible to stably ascend and descend.

Another reinforcing frame is superimposed on the inner or outer peripheral surface of the case to prevent the case from being warped even if the lower portion of the case is opened.

1 is an exploded perspective view
Fig. 2 is a cross-
Fig. 3 is a side sectional view of the state before the falling-
Fig. 4 is a side sectional view
5 is a plan view showing the structure of the power transmission portion
6 is a side schematic view showing the state of use
Fig. 7 is a cross-sectional view of the case in which the reinforcing frame is provided on the inner peripheral surface of the case

Hereinafter, specific configurations and effects of the present invention will be described based on the embodiments shown in the drawings.

The elevator type cabin of the present invention comprises a case 100, a cabinet 200, and an elevation driving unit 300 as shown in Figs. 1 to 3.

First, the case 100 serves as an outer casing of a cabinet, which will be described later, as well as a support for a cabinet, and is formed in a rectangular box shape as a whole.

More specifically, it is formed in a box shape in which a front and a bottom are opened in a state where an installation space 110 for accommodating the storage unit 200 is formed therein, and is installed in a state of being fixed to a wall surface or a ceiling.

A guide rail 120 is formed at a midway point between the left and right inner sides of the case 100. The guide rail 120 is used to connect the case 100 and the storage 200 to be described later, And the like.

The guide rails 120 are formed in a groove shape having a predetermined depth on the left and right inner side surfaces of the case 100 and have a straight rail shape having a length corresponding to the moving distance of the storage space.

At this time, the guide rail 120 is inclined toward the downward direction from the rear end toward the front end so as to form an oblique line as a whole.

Since the lower portion of the case 100 is opened, the bending phenomenon of the case can be generated by the load generated during the lifting and lowering of the storage space.

Therefore, as shown in FIG. 7, the reinforcing frame 101 is formed in a state in which the reinforcing frame 101 is superimposed on the inner circumference of the case, so that the reinforcing frame 101 holds both side walls and the back plate of the case at the same time The bending phenomenon of the case can be minimized.

For reference, the reinforcing frame 101 may be installed on the outer periphery, not on the inner surface of the case, as shown in the figure, and may be formed on both the inner and outer peripheries.

The reinforcement frame 101 is preferably made of a material such as a metal having a high bending strength.

The case 100 further includes a support rail 130 in addition to the guide rail 120.

The support rail 130 is formed to stably support the weight of the stored object including the storage space in the stable mounting and lifting process of the storage space 200. A rail groove 132 having a certain depth as the guide rail 120 is formed And a rail plate 134 is inserted into the rail groove 132.

At this time, the rail grooves 132 are inclined at the same length and angle as the guide rails 120, and are formed on the upper and lower sides with respect to the guide rails 120, respectively.

The rail plate 134 serves to prevent the case from being damaged due to friction between the support rail 130 and the support member 350, And is made of a metal or the like to minimize abrasion due to frictional force.

In addition, a motor mounting groove 140 for mounting a driving motor 310, which will be described later, is further formed on the inner side wall of the rear side of the case 100 formed up to the rail plate 134.

In the case 100 described above, a storage box 200 is provided.

The storage space 200 has a box shape having a size similar to that of the installation space 110 of the case 100 and has a storage space 210 for storing the storage space therein, ) Are formed.

The storage case 200 is inserted into the installation space 110 of the case 100 so that the opening and closing door 220 is exposed to the outside through the front opening of the case 100.

The lifting and lowering driving unit 300 is connected to the cabinet 200 and the case 100.

The lifting drive unit 300 generates a driving force necessary for lifting and lowering the storage 200 and provides a connection function between the storage 200 and the case 100. The lifting drive unit 300 drives the driving motor 310, And a movement guide member 330.

The driving motor 310 is a portion in which the actual driving force is generated among the lifting and driving unit 300. The driving motor 310 is installed in a state of being inserted into the motor mounting groove 140 of the case 100,

As the drive motor 310 is inserted into the motor mounting groove 140, the space consumed by the drive motor in the installation space 110 of the case 100 is minimized.

These drive motors 310 are installed on both sides of the rear wall of the case 100, respectively.

The drive motor 310 is connected to a separate control unit 600 and when an operation control signal is input through a separate operation button 700, the control unit 600 transmits an operation signal to the drive motor 310, The operation of the motor is controlled.

The rotary screw rod 320 transmits the driving force of the driving motor 310 to the cabinet 200 and serves to guide the lifting operation of the cabinet. And a thread groove is formed on the peripheral surface.

The rotating threaded rods 320 are provided in two, and the rear ends of the rotating threaded rods 320 are connected to the motor shaft of the driving motor 310 and are drawn out toward the front side.

At this time, the respective rotation screw rods are positioned in the respective guide rails 120 in a state of being inclined at the same angle as the guide rails 120.

The movement inducing member 330 constituting the lifting drive part 300 together with the driving motor 310 and the rotating screw rod 320 can perform a connecting function between the storage case 200 and the rotary screw rod 320, And is provided in a shape of a rectangular block and protruding from both side walls of the storage unit 200. [

In this state, each of the movement guide members 330 is inserted into both guide rails 120 and installed in a state in which they can move along the longitudinal direction of the guide rails 120.

In this state, the movement guide member 330 is formed in such a manner that the through holes pass through the front and rear ends, and the rotation springs 320 penetrate through the through holes, so that the storage space 200 finally moves the movement guide member 330 And is connected to the rotating screw rod 320 as an intermediate.

As the movement guide member 330 is inserted into the guide rail 120 and the storage space 200 is connected to the rotary screw rod 320, the weight load of the storage space 200 is concentrated on the rotary screw rod 320 And is dispersed in the case 100 through the guide member 330 and the guide rail 120 without being deformed.

Accordingly, the rotation of the rotary screw rod is prevented from being disturbed by the weight of the storage space, and the connection portion between the rotary screw rod and the drive motor is prevented from being damaged.

Since the movement guide member 330 and the rotary screw rod 320 are realized in a general ball screw structure, the movement guide member 330 is rotated in the longitudinal direction of the rotary screw 320 when the rotary screw bar 320 rotates So that the storage space 200 is also linearly moved back and forth in the oblique direction.

The support member 350 is further installed in the storage unit 200 in a state where the lifting drive unit 300 is installed.

The support member 350 serves as an additional support for the storage unit 200 and induces stable up and down movement. The support member 350 is formed in a block shape and protrudes from a position opposite to the support rail 130 on both sides of the storage unit 200 Is inserted into the rail plate (134) of the support rail (130).

Therefore, the support member 350 is also moved along the longitudinal direction of the support rail 130 in the process of moving the storage box 200 back and forth in the oblique direction.

The weight load of the storage box 200 is transmitted in a dispersed state to the case through the guide member 330 and the support member 350 by the coupling structure between the support member and the support rail 130, Respectively.

Although not shown in the drawing, the installation positions of the support rail 130 and the support member 350 may be reversed, that is, the support rails 130 are formed on both sides of the storage space 200, (Not shown).

The support member 350 and the support rail 130 may be omitted if the weight of the storage space 200 can be sufficiently dispersed by only the guide member 330 and the guide rail 120. [

Hereinafter, specific effects generated in the direct use and the process of the present embodiment according to this configuration example will be described.

3, the storage bag 200 and the storage load of the storage bag 200 are moved downward when the storage bag 200 is positioned in the case 100. At this time, the storage bag 200 is supported by the movement guide member 330, The weight load of the storage box 200 is not concentrated on the rotary screw and is dispersed through the movement guide member 330 and the support member 350 And it is transferred to the case.

Therefore, a phenomenon that the connection portion between the rotating screw rod 320 and the driving motor 310 is broken is prevented, and the entire storage space is stably placed in the case.

When the user desires to use the storage space in this state, when the operation button 700 is pressed, each of the driving motors 310 is simultaneously operated according to an operation signal from the control unit 600, Is rotated.

As the rotary screw rod 320 is rotated, the two movement inducing members 330 are moved forward along the longitudinal direction of the rotary screw rod 320, so that the storage space 200 is also linearly moved forward.

At this time, as described above, as the rotary screw rod 320 is positioned in the diagonal direction, the storage box 200 is moved forward and simultaneously descends in the oblique direction.

As described above, since the movement guide member 330 is inserted into the guide rail 120, the movement guide member 330 moves along the formation path of the guide rail 120.

Since the movement guide member 330 is inserted and spanned in the guide rail 120, the load of the storage box is moved in a dispersed state during the movement, so that the guide rail 120 can be moved stably, And is inclined at the same angle as the bobbin 320, so that diagonal draw-out and drop-down of the storage space can be stably performed.

Since the support member 350 is inserted into the support rail 130 together with the movement guide member 330, the load of the storage box 200 is further dispersed in the process of moving the storage box 200 forward, In addition, since the support rail 130 is also formed in the diagonal direction, the diagonal draw-out and drop-down of the storage box 200 can be more stably performed.

When the storage space is sufficiently lowered in the oblique direction so that the movement inducing member 330 or the support member 350 is positioned near the end of the guide rail 120 or the support rail 130, the driving motor is stopped to stop the descent of the storage space .

When the lowering of the cabinet is completed, the user standing in front of the kitchen sink lifts the arm, as shown in FIG. 6, to open and close the cabinet door, and to smoothly take out and store the cabinet inside the cabinet.

In this state, when the operation signal is given again after using the storage space, the drive motor rotates in the opposite direction, and the storage space is inserted in the case while rising in the oblique direction through the reverse process.

A separate sensor 500 may be installed on the movement guide member 330 or the support member 350 to move the movement guide member 330 or the support member 350 in the ascending or descending of the storage space 200, The driving motor 310 may be automatically stopped when the driving motor 310 is positioned near the end of each rail.

The sensor 500 may be formed at the end of the support rail 130 or the guide rail 120 instead of the support member 350 or the movement guide member 330.

As described above, since the lifting and lowering driving unit 300 includes a driving motor and a rotating screw, the structure of the lifting and driving unit 300 is much simpler than that of the conventional link structure.

In addition, since the storage space is simply moved in the linear direction along the longitudinal direction of the rotary screw rod, it is possible to move the storage space more stably than before, and it is not necessary to form a space for preventing collision between the upper surface of the storage space 200 and the upper portion of the case. The problem that the size becomes unnecessarily large can be solved.

In addition, since the weight of the cabinet is dispersed through the guide member, the guide rail, the support member, and the support rail, the cabinet can be stably moved to the weight load and the cabinet can be prevented from falling.

In addition, when the rotary screw rod 320, the drive motor 310, the movement guide member 330, and the support member 350 are both inserted into the guide rail 120, the support rail 130, and the motor installation groove 140 The additional space required for the installation of the above configuration is not generated, so that the phenomenon that the total size becomes unnecessarily large can be solved.

5 is a view showing an example of various modifications of the present invention,

The basic structure in which the rotation screw rod 320, the movement guide member 330 and the support member 350 are provided is the same as that of the above embodiment. On the other hand, the structure of the lifting and lowering driving unit 300 is modified, There is a difference in that the rotation speed and the operation timing of the both rotary rods 320 can be exactly matched at all times while reducing the number of installation.

More specifically, the driving motor 310 is connected to only one of the two rotating swivel rods 320, and the power transmission unit 400 is additionally provided.

At this time, a rear end portion of a rotary screw rod (hereinafter referred to as a 'driven rod 324') not connected to the driving motor is installed to be rotatably connected to the rear side wall surface of the case.

The power transmission unit 400 transmits the rotational force of a rotary screw rod 322 connected to the driving motor 310 to a driven screw rod 324 located on the opposite side ,

A driving circuit unit 410 in the form of a pulley or a sprocket is connected to the rear end of the driving screw rod 322 and a driving coil 410 is connected to the rear end of the driven screw rod 324, And the driving circuit body 410 and the driven circuit body 420 are connected to each other through a connection member 430 such as a belt or a chain.

Due to such a structure, the driving screw 322 is rotated by the driving motor 310, and the driven rod 324 simultaneously rotates through the connecting body 430 and the rotational speed is also the same.

If a separate driving motor is connected to each rotating shaft and the rotating shaft, there may be a difference in operation timing and rotational speed of each rotating shaft depending on the state of each driving motor. In this case, A phenomenon may occur in which the storage unit 200 is shifted to one side due to the driving force variation.

However, when the power transmitting portion is provided as described above, the driving and bending rod 322 and the driven and bending rod 324 can be rotated at the same timing and speed at all times.

Although it is not shown in the figure, a door in the form of a hinged door may be installed at a lower portion of the case 100, so that the door is automatically opened while the door is lowered. In this case, Like the reinforcing frame 101 of the above embodiment, can reinforce the case.

At this time, an elastic member such as a torsion spring may be installed on the hinge portion of the door so that the door can be closed automatically in the process of ascending the storage space.

In addition, the opening and closing doors of the cabinet are omitted, and the opening and closing doors are provided on the front surface of the case, so that the opening and closing door is automatically opened by pushing the opening and closing door forward while the cabinet is lowered. .

FIG. 8 to FIG. 11 are views showing another embodiment of the present invention,

Basically, the basic concept of obtaining the lift driving force by using the rotary screw rod 320 is the same as the above embodiment, but the difference is that the conveying wire 800 is used in transmitting the lift driving force to the storage space 200. [

More specifically, in this embodiment, the space portion 1 is provided between the rear surface of the storage box 200 and the rear surface of the case 100 in a state in which the storage box 200 is completely housed in the case 100, .

At this time, a motor shaft of the driving motor 310 is positioned so as to face upward, and a structure capable of rotating forward and backward is used for the driving motor 310.

The driving motor 310 is electrically connected to an operation switch or other remote control installed in a case or the like so that the user can control the operation from outside the case.

In this state, the rotating shaft 320 is connected to the motor shaft,

The rotating screw rod 320 is a part for outputting the driving motor 310 for the first time in the same manner as in the above embodiment and is also in the form of a ball screw, It is installed in a connected state.

In this state, the upper end of the rotary screw rod 320 is supported by a separate bearing housing B, which serves to support the rotary screw rod 320 and to induce smooth rotation. And a structure in which a bearing is embedded in the inside.

The bearing housing B is located on the upper side of the face of the case 100 facing the rear surface of the storage case 200 and the upper end of the rotating screw rod 320 is positioned in a state where it is sandwiched by an inner bearing.

Accordingly, the rotary screw rod 320 has a structure in which the upper and lower ends thereof are rotated while being connected to the drive motor 310 and the bearing housing B, respectively.

In this state, a straight guide rail 920 is provided on the rear side of the case 100. [

The linear guide rail 920 serves to guide the linear movement of the transport block 910, which will be described later, when the rotary screw rod 320 is rotated. The linear guide rail 920 has a bar shape approximately the same length as the rotary screw rod 320, And is positioned so as to face the rotating screw rod 320 in a horizontal state on the inner side of the rotating shaft 320.

 At this time, guide grooves for coupling with the transport block 910, which will be described later, are formed along the longitudinal direction at both sides of the linear guide rail 920.

For reference, the linear guide rail 920 may be embedded in the case in addition to the structure protruding from the rear surface of the case, or a protrusion structure may be applied instead of the guide groove.

In the state where the linear guide rails 920 are installed, the transfer screw 910 is installed on the rotary screw rod 320.

The transfer block 910 serves to first transfer the rotational force of the rotary screw rod 320 to the transfer wire 800 to be described later. The transfer block 910 has a rectangular block shape and includes a screw hole corresponding to the thread of the rotary screw rod 320 And is formed in a vertically penetrating shape.

In this conveying block 910, a rotary screw rod 320 is coupled through the screw hole and a groove (not shown) in the form of a rail for sliding engagement with the linear guide rail is formed on the rear surface.

In this state, as the linear guide rails 920 are inserted into the grooves of the transport block, the transport blocks 910 are moved in the vertical direction along the length direction of the linear guide rails 920 without being rotated during the rotation of the rotary screw bar 320 .

The lifting and lowering roller portion is provided on one side of the rotary bar shaft 320 on which the conveying block 910 is installed.

The elevating roller unit finally serves to transfer the lifting force of the conveying block 910 to the storage box 200 and further includes a supporting piece 930 and a conveying roller 940.

 The supporting piece 930 serves as a support for fixing the conveying roller 940, which will be described later, and is fixedly installed at a position near the side of the rotation screw bar 320 in the rear side of the case.

The supporting piece 930 can be variously modified if it is possible to install the conveying roller 940 such as a simple plate material. Further, if the conveying roller 940 can be installed directly on the case, the supporting piece can be omitted Do.

The conveying roller 940 serves to transmit the lifting force of the conveying block 910 to the conveying wire 800 to be described later. The conveying roller 940 is in the form of a general roller and both side portions are fixed to the supporting piece 930 through the central shaft, And is rotatable around the axis.

As the transporting roller 940 is positioned to face the rear midpoint of the storage space 200, the transporting wire 800, which will be described later, is connected to the middle of the rear side of the storage space, So that it can be uniformly applied without being shifted to either side.

In this state, the conveying wire 800 is connected to the conveying roller 940.

The conveying wire 800 finally transfers the lifting force of the conveying block 910 to the cabinet 200 to finally output the driving force necessary for the actual lifting and lowering of the conveying block 900. The conveying wire 800 is conveyed in a state of being connected to the conveying block 910, Is wound around the roller (940).

In this state, the other end of the transfer wire 800 is connected to the rear surface of the storage unit 200. At this time, the transfer wire 800 is connected to the rear midpoint of the storage unit 200, Do not bias the driving force to either side of the storage space.

Accordingly, the conveying wire 800 has a structure in which the storage space 200 connected to the conveying block 800 is lifted and lowered as the conveying block 910 is pulled and unfolded around the conveying roller 940 at the time of ascending and descending.

For reference, the transfer wire has sufficient strength by itself such as a metal wire, so that breakage does not occur even if it is used for a long time.

Also in this embodiment, the rail groove 132 is formed on both inner side surfaces of the case 100 in an oblique direction inclined downward toward the front side, and the rail plate 134 is inserted into the rail groove 132.

In this state, a support member 350 is protruded from both sides of the storage unit 200, and the support member 350 is inserted into the rail plate 134.

Therefore, the storage unit 100 has a structure in which the lifting and lowering is induced in the diagonal direction during the lifting and lowering by the transfer wire 800.

Hereinafter, the operation of this embodiment by this structure and the effect generated in the process will be described.

10, when the storage box 200 is completely inserted into the case 100, the transfer block is positioned at the lower end of the rotary screw rod 320 and the transfer wire 800 is completely pulled. As a result, The storage space 200 is pulled by the pulling force of the conveying wire 800 and the position is fixed.

When it is desired to lower the storage compartment 200 in this state,

When the drive motor 310 is operated, the rotary screw rod 320 is rotated so that the transfer block 910 is linearly moved along the longitudinal direction of the rotary screw rod 320 and the linear guide rail.

As the conveying block 910 is raised, the other end of the conveying wire 800 is loosened with respect to the conveying roller 940, whereby the storage box 200 is lowered due to its own weight.

At this time, since the conveying wire 800 is always pulled tightly to maintain the proper tension, the storage device 200 is gradually lowered only by the release length of the conveying wire at the time of descending.

Since the supporting member 350 is inserted into the rail plate 134 in the process of descending the cabinet 200, the cabinet 200 is lowered in the diagonal direction, .

On the other hand, when the storage unit 200 is to be raised, the storage unit rises through the process opposite to the above and is placed in the inserted state in the case.

As described above, according to the present embodiment, since the driving force of the rotary screw rod is transmitted to the storage space through the feed roller 940 and the feed wire 800, unlike the above embodiment, it is not necessary to install the rotary screw in the rail plate, It is not necessary to install both the rotary rods and the rods in both sides of the cabinet, which is advantageous in terms of structure.

FIG. 12 is a view showing a modified structure of an embodiment in which such a transfer wire is knitted. In this embodiment, the end portion of the transfer wire 800 is divided into several sections so that each of the divided branches 810 is located at a mid- And to be connected to both sides at the same time.

As a result, not only the lifting force by the conveying wire is uniformly distributed over the entire rear surface of the cabinet but also the load applied to the conveying wire is also divided into the divided portions, so that the lifting of the cabinet is induced smoothly, .

[Fig. 13] and [Fig. 14] are diagrams showing yet another modified example,

The support member 350 and the rail plate 134 are provided with a separate safety device to prevent the storage space from falling below the case when the transfer wire is broken.

As shown in the drawing, a plurality of buried grooves 352 are formed on the bottom surface of the support member 350 along the longitudinal direction of the support member 350, A spring 354 is inserted and installed.

A latching piece 353 is located at the end of the spring 354 in the inside of the buried groove 352.

In addition, a plurality of latching grooves 135 are formed on the inner surface of the rail plate 134 in the vicinity of the lower end thereof with intervals along the longitudinal direction.

The engaging piece 353 comes into contact with the rail plate 134 to be pressed against the rail plate 134 when the engaging piece 353 is positioned in the upper portion of the rail plate 134 above the point where the engaging groove 135 is formed, The spring 354 is compressed and positioned in each of the buried grooves 352.

The engaging groove 135 is positioned below the maximum descending point of the storage space of the rail plate 134, that is, the maximum descending point of the supporting member 350.

With this structure, if the conveying wire is broken during the descending of the storage 200, the storage space is lowered due to its own weight. In this process, when each retaining piece 353 is positioned at the position of the retaining groove 135, The engaging pieces 353 are pulled out and fit into the engaging grooves 135.

Due to the coupling force between the latching piece 353 and the latching groove 135, the storage device 200 is not lowered any more.

While the present invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. The present invention should be considered to fall within the scope of protection of the present invention when it is related to a configuration and purpose of simplifying the overall structure as well as enabling a stable rise and fall compared with the existing one.

100: Case 110: Installation space
120: guide rail 130: support rail
132: rail groove 134: rail plate
140: motor mounting groove 200: cabinet
210: storage space 220: opening / closing door
300: lifting drive part 310: drive motor
320: rotating screw bar 330: moving guide member
350: support member 400: power transmission portion
410: Driving circuit full 420:
430: connector body 322:
324: Sutdongsa and Sangbong 500: Sensor
600: control unit 700: operation button

Claims (5)

A case having a front and a bottom opened and an installation space formed therein,
A storage space accommodated in the installation space so as to be drawn out and having a storage space therein,
A drive motor located at a position between a rear surface of the storage space and a position between the case in the installation space,
And a lower end portion connected to the driving motor so as to be rotatable,
A movement guide member connected to the rotary screw rod and movable up and down in the longitudinal direction of the rotary screw rod when the rotary screw rod is rotated,
A conveying roller located on one side of the rotary screw rod,
And a conveying wire having one end connected to the up-and-down moving guide member and the other end connected to the cabinet in a state in which the conveying roll is spanned,
Wherein a section of the conveying wire extending from a point across the conveying roller to a point connected to the cabinet is divided into a plurality of sections and connected to the cabinet separately
Lifting cabinet. The method of claim 1,
On both side walls of the case, there are formed rail grooves inclined downward toward the front side,
A support member fixed to the side wall of the cabinet and connected to the rail groove to be movable along the rail groove when the cabinet is lifted or lowered,
Further comprising:
delete 3. The method of claim 2,
A linear guide rail positioned in a horizontal state with the rotary screw,
Wherein the guide member is coupled to the linear guide rail in a state of being connected to the movement guide member and moves up and down along the length direction of the linear guide rail together with the movement guide member in the up-
Further comprising:
Wherein the transfer wire is connected to the movement guide member via the transfer block
Lifting cabinet.
3. The method of claim 2,
A plurality of engaging grooves formed at the bottom of the lower end of the rail groove,
A buried groove arranged on the bottom surface of the support member at the same number and spacing as the engaging grooves,
A spring formed in each of the buried grooves,
And an engaging portion which is connected to an end portion of the spring and which is located in the buried groove in a state capable of being drawn out of the respective buried grooves by an elastic force of a spring,
And an elevator cabinet.

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