CN219479545U - Spare part data storage cabinet for transformer substation - Google Patents

Abstract

The utility model provides a spare part data storage cabinet for a transformer substation, which relates to the technical field of storage cabinets and comprises the following components: the cabinet body is internally provided with a plurality of layers of transverse plates which extend transversely, and an interlayer is formed between two adjacent transverse plates; the partition piece is longitudinally and rotatably connected to the transverse plate above each interlayer, and can be abutted against the bottom end surface of the transverse plate when swinging to a horizontal state; and the sliding mechanism is arranged on the transverse plate and connected with the partition piece to drive the partition piece to transversely slide and lock. The utility model solves the problem of the prior art that the space utilization rate of the storage of the data cabinet is reduced due to the sliding type partition piece.

Description

Spare part data storage cabinet for transformer substation

Technical Field

The utility model relates to the technical field of storage cabinets, in particular to a spare part data storage cabinet for a transformer substation.

Background

Conventional data cabinets typically include multiple interlayers, and when document data is not fully stored in the interlayers, particularly in a transformer substation, a large amount of statistical information about facilities or electricity consumption of residents in surrounding areas needs to be generated daily, and in the process of continuously storing or taking out the information documents, the documents in the data cabinet are easily inclined and slide down, so that the document distribution in the data cabinet is disordered.

For solving the problem that files are loose respectively and easy to slide off in the data cabinet, the patent application with the publication number of CN211380261U provides a medical insurance department data regulation filing cabinet, which controls the left and right sliding of a partition plate to adjust and change the width of the interlayer, so that the partition plate can be always abutted against the files, and the storage stability of the files in the filing cabinet is further enhanced.

However, in the structure of the data cabinet with adjustable storage width, when the layer of data is fully stored, the space occupied by the partition plate, the sliding mechanism and the wall surface of the cabinet can influence the continuous storage of the data, so that the space utilization rate of the data cabinet is reduced.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model provides a spare part data storage cabinet for a transformer substation, which solves the problem that the space utilization rate of the data cabinet for storage is reduced due to a sliding partition piece in the prior art.

According to an embodiment of the present utility model, a spare part data storage cabinet for use in a transformer substation includes:

the cabinet body is internally provided with a plurality of layers of transverse plates which extend transversely, and an interlayer is formed between two adjacent transverse plates;

the partition piece is longitudinally and rotatably connected to the transverse plate above the interlayer, and can be abutted against the bottom end surface of the transverse plate when swinging to a horizontal state;

and the sliding mechanism is arranged on the transverse plate and connected with the partition piece to drive the partition piece to transversely slide and lock.

Compared with the prior art, the utility model has the following beneficial effects: through with traditional partition member swivelling joint on the upper cross plate, make it can swing to the clearance between material and the upper cross plate when the required storage data of intermediate layer is great to deposit and hide above-mentioned partition member, make partition member and slide mechanism can not hinder the normal storage of material, and then maximize the space utilization who improves this filing cabinet.

Further, the partition member includes:

the rotating shaft is longitudinally and rotatably connected to the transverse plate, one end of the rotating shaft penetrates out of the transverse plate, and the end of the rotating shaft extends transversely and then is vertically and downwards bent to form a first bending section;

and the top end of the partition layer is fixedly connected with the free end of the first bending section.

Further, the sliding mechanism includes:

the guide rail is arranged on the transverse plate and transversely extends, a sliding block is connected to the guide rail in a sliding manner, and the rotating shaft longitudinally passes through the sliding block and is in clearance fit with the sliding block;

and the first limiting mechanism and the second limiting mechanism are both arranged on the transverse plate so as to prevent the sliding block from sliding randomly and the rotating shaft from rotating randomly.

Further, the first limiting mechanism includes:

the clamping grooves are provided with a plurality of clamping grooves and are transversely and uniformly distributed on the transverse plate, and the opening of each clamping groove is longitudinally arranged;

and one end of the second bending section transversely extends and is fixedly connected with the rotating shaft, the other end of the second bending section vertically extends and can be clamped in any clamping groove.

Further, the second limiting mechanism comprises a first limiting chute and a second limiting chute which are arranged on the sliding block, and each limiting chute extends longitudinally;

the rotating shaft is also provided with limiting protrusions extending in the same direction, and the limiting protrusions can slide into the limiting sliding grooves along the longitudinal direction to limit the rotating shaft to continuously rotate.

Furthermore, both ends of the transverse plate are respectively provided with a transversely extending slideway, and both ends of the rotating shaft can slide along each slideway respectively.

Further, the free end of the second bending section is fixedly connected with the partition layer.

Further, a magnet is arranged in the opening of each clamping groove, and a corresponding magnet is arranged at the corresponding position of the second bending section.

Further, a scale is arranged on the end face of the transverse plate, and a plurality of scale marks on the scale are arranged right opposite to the opening of the clamping groove.

Further, at least two partition pieces are arranged on the same layer.

Drawings

Fig. 1 is a schematic diagram of an external structure of an embodiment of the present utility model.

Fig. 2 is a schematic view of the internal structure of fig. 1 with the cabinet body and the top plate of the cross plate removed.

Fig. 3 is a partial enlarged view at a in fig. 2.

In the above figures: 1. a cabinet body; 2. a cross plate; 3. a partition member; 301. a rotating shaft; 302. a first bending section; 303. a barrier layer; 4. a guide rail; 5. a slide block; 6. a clamping groove; 7. a second bending section; 8. the second limiting chute; 9. a limit protrusion; 10. a slideway; 11. a limit opening; 12. and (5) an installation port.

Detailed Description

The technical scheme of the utility model is further described below with reference to the accompanying drawings and examples.

As shown in fig. 1, an embodiment of the present utility model provides a spare part data storage cabinet for use in a substation, including:

the cabinet body 1 is internally provided with a plurality of layers of transverse plates 2 which extend transversely, in this embodiment, the transverse direction, the longitudinal direction and the vertical direction respectively correspond to the length direction (i.e. the left-right direction in fig. 1), the width direction and the height direction (i.e. the up-down direction in fig. 1) of the cabinet body 1, the front end face and the rear end face referred to in the following text take one side which is close to the opening and closing door of the cabinet body 1 in the longitudinal direction as the front end face, an interlayer is formed between two adjacent transverse plates 2, the interlayer can be used for accommodating various file data, and the transverse plates 2 are composed of an upper top plate, a lower bottom plate and four side plates, so that a containing cavity is formed inside the transverse plates;

the partition piece 3 is connected to the transverse plate 2 above each interlayer in a longitudinal rotation manner, can be used for partitioning the interlayer to change the size of the interlayer of the contained data file when the partition piece 3 is in a vertical state, and can be abutted against the bottom end surface of the transverse plate 2 to contain the partition piece 3 when the partition piece 3 swings to a horizontal state;

and a sliding mechanism mounted on the transverse plate 2 and connected with the partition member 3 to drive the partition member 3 to slide laterally and lock.

According to the embodiment, the traditional partition member 3 is rotatably connected to the upper-layer transverse plate 2, so that the partition member 3 can swing into a gap between the data and the upper-layer transverse plate 2 when the required storage data of the interlayer is more, and the partition member 3 is stored and hidden, so that the normal storage of the data can not be hindered by the partition member 3 and the sliding mechanism thereof, and the space utilization rate of the data cabinet is improved maximally.

Further, as shown in fig. 2, the partition member 3 includes a rotating shaft 301, a first bending section 302 and a partition layer 303, the sliding mechanism includes a guide rail 4, the guide rail 4 is fixedly disposed in the transverse plate 2 and extends transversely, the guide rail 4 is slidably connected with a sliding block 5, the rotating shaft 301 longitudinally passes through the sliding block 5 and is in clearance fit with the sliding block, one end of the rotating shaft 301 passes through a side plate of the transverse plate 2, and after the end extends transversely, the end is vertically bent downwards to form a first bending section 302, a free end (i.e. a bottom end) of the first bending section 302 is fixedly connected with the partition layer 303, in this embodiment, in order to reduce the weight of the partition layer 303, the bottom end of the bending section extends downwards and continues to be bent, so that after the rotating shaft 301 swings anticlockwise by 90 °, the bending section and the partition layer 303 can rotate anticlockwise around the axis of the rotating shaft 301 as a circle center, and then the partition layer 303 can cross the bottom plate 2 through the transverse section of the section, thereby realizing that the horizontal utilization rate of the space of the interlayer 2 is increased; meanwhile, the bending and folding arrangement of the isolating layer 303 can also be used as a handrail for facilitating the later pulling or pushing of the isolating layer 303 by a user.

Further, both ends of the transverse plate 2 (i.e. on the side plates at the front and rear ends) are respectively provided with a transversely extending slide rail 10, and both ends of the rotating shaft 301 can slide along each slide rail 10 respectively, thereby supporting and guiding the rotating shaft 301.

Of course, the transverse plate 2 is also provided with a first limiting mechanism for preventing the sliding block 5 from sliding randomly and a second limiting mechanism for preventing the rotating shaft 301 from rotating randomly, the first limiting mechanism can be a linear propulsion mechanism with a self-locking function, such as a screw rod, at the moment, the screw rod can be transversely connected to the vertical wall surface of the cabinet body 1 and penetrates out of the cabinet body 1, one end penetrating out of the cabinet body 1 is provided with a hand wheel, the screw rod simultaneously penetrates through the sliding block 5 and is in threaded connection with the sliding block 5, on one hand, the hand wheel can be rotated to drive the sliding block 5 to slide transversely by using the screw rod, and the sliding block 5 can be locked when the screw rod stops rotating; the second driving mechanism may be a bolt, in which part of the pin holes are uniformly distributed on the front end surface of the transverse plate 2 along the transverse direction, and the transverse section and the vertical section of the first bending section 302 are also provided with pin holes, at this time, when the partition layer 303 rotates to the vertical state, the bolt can be inserted into the pin holes on the transverse plate 2 through the pin holes on the vertical section to limit the continuous rotation of the rotating shaft 301, or when the partition layer 303 rotates to the horizontal state, the bolt can be inserted into the pin holes on the transverse plate 2 through the pin holes on the transverse section to limit the continuous rotation of the rotating shaft 301.

The present utility model proposes another embodiment, which is different from the above embodiment in that the present embodiment provides a first limiting mechanism and a second limiting mechanism that are more convenient for a user to operate, wherein,

as shown in fig. 2, the first limiting mechanism includes:

the clamping grooves 6 are provided with a plurality of clamping grooves and are transversely and uniformly distributed on the transverse plate 2, the openings of the clamping grooves 6 are longitudinally arranged, and the connecting clamping grooves 6 are smoothly transited to facilitate the clamping connection of the second bending section 7;

and a second bending section 7, one end of which extends transversely and is detachably and fixedly connected with the rotating shaft 301, the other end of which extends vertically and the end of which can be clamped in any clamping groove 6, wherein the shape and the bending direction of the second bending section 7 and the first bending section 302 are the same.

As shown in fig. 3, the second limiting mechanism comprises a first limiting chute and a second limiting chute 8 which are arranged on the sliding block 5, each limiting chute extends longitudinally, and the two limiting chutes are distributed at 90 degrees relative to the axis of the rotating shaft 301;

as shown in fig. 2 and fig. 3, the wall surface of the rotating shaft 301 is fixedly provided with a limiting protrusion 9 extending in the same direction, the limiting protrusion 9 may slide into the limiting chute along any longitudinal direction to limit the rotating shaft 301 to continue rotating, when the partition layer 303 is in a vertical state, the limiting protrusion 9 extends into the first limiting chute (located on the right side of the rotating shaft 301, in fig. 3, the limiting protrusion 9 is located in the first limiting chute), and when the partition layer 303 is in a horizontal state, the limiting protrusion 9 extends into the second limiting chute 8 (located above the rotating shaft 301).

In the above structure, when a user needs to add or take out document data in the interlayer, the separating layer 303 is pulled to drive the rotating shaft 301 to slide longitudinally, so that the second bending section 7 and the limiting protrusion 9 respectively exit the clamping groove 6 and the first limiting chute, then the separating layer 303 is pulled transversely to adjust the width of the interlayer, finally the separating layer 303 is pushed reversely and the rotating shaft 301 is driven to slide longitudinally again, so that the second bending section 7 and the limiting protrusion 9 slide into the clamping groove 6 and the first limiting chute again, the clamping groove 6 can abut against the second bending section 7 through the wall surface thereof to prevent the separating layer 303 from sliding freely along the transverse direction, and the first limiting chute clamps the limiting protrusion 9 to prevent the rotating shaft 301 from rotating randomly;

when the user needs to store the isolating layer 303, the isolating layer 303 is pulled to drive the rotating shaft 301 to longitudinally slide, so that the second bending section 7 and the limiting protrusion 9 respectively exit the clamping groove 6 and the first limiting sliding groove, then the isolating layer 303 is rotated to be in a horizontal state, and then the isolating layer 303 is pushed reversely again, so that the limiting protrusion 9 slides into the second limiting sliding groove 8, and the transverse section of the original second bending section 7 is clamped in the clamping groove 6, and finally the storing of the isolating layer 303 and the limiting thereof is completed; in order to enhance the longitudinal limitation of the storage cabinet to the rotating shaft 301, so as to provide a feedback to the user about whether the pulling amplitude is enough to ensure that the second bending section 7 is completely separated from the clamping groove 6 when the isolating section 303 is pulled, the bottom plate of the transverse plate 2 is provided with a limiting opening 11, the clamping groove 6 is arranged on the end face of the limiting opening 11 opposite to each bending section, at this time, when the isolating section 303 is pulled to drive the rotating shaft 301 to slide longitudinally, the user can pull the isolating section 303 until the second bending section 7 abuts against the end face of the other end of the limiting opening 11 opposite to the clamping groove 6, and then the isolating section 303 can be rotated or slid to complete the subsequent operation.

Further, as shown in fig. 2, in order to enhance the limiting effect of the clamping groove 6 on the second bending section 7, a magnet is fixed in the opening of each clamping groove 6, and a corresponding magnet is disposed at the corresponding position of the second bending section 7 (in this embodiment, the second bending section 7 is made of ferrous metal and can be used as a magnet), in this structure, the rotating shaft 301 can be prevented from driving the second bending section 7 to slide out of the clamping groove 6 due to loosening, so as to enhance the clamping effect of the clamping groove 6 on the second bending section 7.

Furthermore, the end surface of the transverse plate 2 is fixedly provided with a scale, a plurality of scale marks on the scale are arranged in one-to-one correspondence with the openings of the clamping grooves 6, and it is to be understood that the front end surfaces of the clamping grooves 6 are all in arc transition arrangement, so that a user can slide the second bending section 7 into the clamping groove 6 more conveniently in the actual use process; the arrangement of the scale is to facilitate the user to directly and obviously observe the clamping position of the second bending section 7.

Further, the free end (bottommost end) of the second bending section 7 is fixedly connected with the partition layer 303, so that the partition layer 303 is fixedly connected at a plurality of positions, and the stability of the partition layer 303 is further enhanced.

For installation, the left and right sides of the transverse plate 2 can be provided with the sliding blocks 5 to slide into the installation openings 12 of the guide sliding rails, in this structure, when the storage cabinet is assembled, the sliding blocks 5 can be firstly slid into the installation openings 12, then the rotating shaft 301 is slid into and passes through the sliding blocks 5 through the sliding way 10 of the front end face of the transverse plate 2 until being inserted into the sliding way 10 of the rear end face of the transverse plate 2, and finally the second bending section 7 is installed.

The present utility model proposes another embodiment, which is different from the above embodiment in that the present embodiment provides another arrangement manner of the partition member 3 to meet the actual needs, where the partition member 3 located on the same layer is at least provided with two, in this embodiment, the partition member 3 and the sliding mechanism are both provided with two along the transverse direction, at this time, in the same layer of interlayer, when one type of document is not fully saved (or the document itself is less, and is not easy to fully occupy the interlayer), the other partition member 3 can be slid to press the other type of document against the other side of the interlayer to realize the respective fixing of the same interlayer to the different types of document.

The working process of the utility model is as follows: when a user needs to add or take out document data in the interlayer, firstly, the separation layer 303 is pulled to drive the rotating shaft 301 to longitudinally slide, so that the second bending section 7 and the limiting protrusion 9 respectively exit the clamping groove 6 and the first limiting chute, then, the separation layer 303 is transversely pulled to adjust the width of the interlayer, finally, the separation layer 303 is reversely pushed and the rotating shaft 301 is driven to longitudinally slide again, so that the second bending section 7 and the limiting protrusion 9 slide into the clamping groove 6 and the first limiting chute again, and the clamping groove 6 can prop against the second bending section 7 through the wall surface of the clamping groove 6 to prevent the separation layer 303 from freely sliding along the transverse direction, and the first limiting chute clamps the limiting protrusion 9 to prevent the rotating shaft 301 from rotating randomly;

when the user needs to store the isolating layer 303, the isolating layer 303 is pulled to drive the rotating shaft 301 to longitudinally slide, so that the second bending section 7 and the limiting protrusion 9 respectively exit the clamping groove 6 and the first limiting sliding groove, and then the isolating layer 303 is rotated to be in a horizontal state, and then the isolating layer 303 is pushed reversely again, so that the limiting protrusion 9 slides into the second limiting sliding groove 8, and the transverse section of the original second bending section 7 is clamped in the clamping groove 6, and finally the storing of the isolating layer 303 and the limiting thereof is completed.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (10)

1. A spare part data storage cabinet for use in a substation, comprising:

a cabinet body (1) is internally provided with a plurality of layers of transverse plates (2) which extend transversely, and an interlayer is formed between two adjacent transverse plates (2);

a partition member (3) rotatably connected to the cross plate (2) above the interlayer in the longitudinal direction, wherein the partition member (3) can abut against the bottom end surface of the cross plate (2) when swinging to a horizontal state;

and the sliding mechanism is arranged on the transverse plate (2) and connected with the partition piece (3) to drive the partition piece (3) to transversely slide and lock.

2. A spare parts data storage cabinet for use in a substation according to claim 1, wherein the partition (3) comprises:

the rotating shaft (301) is connected to the transverse plate (2) in a longitudinal rotating way, one end of the rotating shaft (301) penetrates out of the transverse plate (2), and the end extends transversely and then is bent vertically downwards to form a first bending section (302);

and a partition layer (303) the top end of which is fixedly connected with the free end of the first bending section (302).

3. The spare parts data storage cabinet for use in a transformer substation as set forth in claim 2, wherein the slide mechanism comprises:

the guide rail (4) is arranged on the transverse plate (2) and transversely extends, the guide rail (4) is connected with a sliding block (5) in a sliding manner, and the rotating shaft (301) longitudinally penetrates through the sliding block (5) and is in clearance fit with the sliding block;

and the first limiting mechanism and the second limiting mechanism are both arranged on the transverse plate (2) to respectively prevent the sliding block (5) from sliding randomly and the rotating shaft (301) from rotating randomly.

4. A spare part data storage cabinet for use in a substation as claimed in claim 3, wherein said first limit mechanism comprises:

the clamping grooves (6) are arranged and are uniformly distributed on the transverse plate (2) along the transverse direction, and the opening of each clamping groove (6) is longitudinally arranged;

and one end of the second bending section (7) transversely extends and is fixedly connected with the rotating shaft (301), the other end of the second bending section vertically extends and can be clamped in any clamping groove (6).

5. A spare parts data storage cabinet for use in a substation as claimed in claim 3 or 4, wherein: the second limiting mechanism comprises a first limiting chute and a second limiting chute (8) which are arranged on the sliding block (5), and each limiting chute extends longitudinally;

the rotating shaft (301) is also provided with limiting protrusions (9) extending in the same direction, and the limiting protrusions (9) can slide into each limiting sliding groove along the longitudinal direction to limit the rotating shaft (301) to continuously rotate.

6. A spare parts data storage cabinet for use in a substation as claimed in claim 2, wherein: both ends of the transverse plate (2) are provided with transversely extending slide ways (10), and both ends of the rotating shaft (301) can slide along the slide ways (10) respectively.

7. The spare parts data storage cabinet for use in a transformer substation as claimed in claim 4, wherein: the free end of the second bending section (7) is fixedly connected with the partition layer (303).

8. The spare parts data storage cabinet for use in a transformer substation as claimed in claim 4, wherein: magnets are arranged in the openings of the clamping grooves (6), and corresponding magnets are arranged at the positions corresponding to the second bending sections (7).

9. The spare parts data storage cabinet for use in a transformer substation as claimed in claim 4, wherein: the end face of the transverse plate (2) is provided with a scale, and a plurality of scale marks on the scale are respectively opposite to the openings of the clamping grooves (6).

10. A spare parts data storage cabinet for use in a transformer substation according to any one of claims 1-4 or 6-9, wherein: at least two partition pieces (3) are arranged on the same layer.