CN209891774U - Multi-section splicing type shared rest cabin - Google Patents

Abstract

The utility model relates to a multi-section splicing type shared rest cabin, which comprises a rest cabin body and a plurality of wires, wherein the rest cabin body comprises a plurality of sections of prefabricated cabin bodies which are spliced in sequence; the plurality of wires are laid and fixed on the rest cabin body, when all or part of the plurality of wires need to be laid through the prefabricated cabin bodies in different sections, the part of the wire corresponding to the prefabricated cabin bodies in different sections is divided, each divided section of wire is still laid on the prefabricated cabin bodies in different sections according to the laying scheme of the original whole wire, male and female plugs for plugging are respectively arranged at the butt joint parts of adjacent sections of wires, and each divided section of wire can be conducted and restored through plugging of the male and female plugs. The utility model provides a multistage concatenation formula sharing rest cabin adopts the modular design, is favorable to disassembling and shifting of sharing rest cabin.

Description

Multi-section splicing type shared rest cabin

Technical Field

The utility model relates to an article sharing technical field, concretely relates to sharing rest cabin of multistage concatenation formula.

Background

At present, only seats are basically arranged in airport waiting rooms or station waiting rooms, passengers can only passively sit for waiting for departure, and people feel tired after sitting for a long time. When the flight delay is encountered, the passengers suffer from physical and mental double suffering.

In addition, many people on duty in an office building do not have a condition for having a bed for noon break, and even if they can use a folding bed for noon break, they have to endure discomfort of excessive ambient light and loud ambient noise.

Although some shared rest devices are available on the market, most of the common rest devices are in a space provided by the market, and the structure of the common rest devices is not optimized. For example, chinese utility model patent application with application number 201710430857.0 discloses "a lodging device, including the box, the box is internal to be constructed has the space that is used for the lodging, be equipped with the door on the box, the lodging device still includes: an electronic door lock; and the control system is used for receiving a control instruction sent by the server and opening the electronic door lock according to the control instruction. The utility model also provides a lodging system and the management method of lodging system and realize the storage medium of this method that contain this lodging device. The utility model discloses a lodging device can make the lodging personnel when the lodging, need not get the door card, can send the instruction of opening of electronic lock by the system to long-range server request back through user equipment. Therefore, the accommodation personnel can live in the room by themselves, the personnel are not needed to assist in handling the live-in procedures, a large amount of labor cost and management cost are saved, and although the technical scheme solves the problem of how to manage and use the accommodation device (shared rest device), the structure of the accommodation device is integrated, so that the transportation and the putting in of the device are difficult and troublesome, and the popularization of the shared rest device is influenced.

At present, the whole production is finished in a factory, and the whole shared rest device is placed on a transport tool to be carried back and forth. Because the shared rest device is a hollow structure with larger integral volume, only a small number of shared rest devices can be transported at one time due to the limitation of volume, and the load-carrying function of the transport tool cannot be fully utilized.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: a multi-section splicing type shared rest cabin convenient to assemble, put in and transport is provided.

The utility model discloses a solve the technical scheme that above-mentioned technical problem provided and be: the utility model provides a rest cabin is shared to multistage concatenation formula, includes rest cabin body, forceful electric power load, light current load, power management module and is connected to respectively a plurality of wires of forceful electric power load and/or light current load which characterized in that:

the rest cabin body comprises a plurality of sections of prefabricated cabin bodies which are sequentially spliced;

the plurality of wires are laid and fixed on the rest cabin body, when all or part of the plurality of wires need to be laid on prefabricated cabin bodies in different sections, the part of the wire corresponding to the prefabricated cabin bodies in the different sections is divided, each divided section of wire is still laid on the prefabricated cabin bodies in the different sections according to the original laying scheme of the whole wire, male and female plugs for plugging are respectively arranged at the butt joint parts of the adjacent sections of wire, and each divided section of wire can be conducted and restored through plugging of the male and female plugs.

Further, the weak current load comprises a control unit and a network communication module, and the control unit is connected to a remote background server through the network communication module;

the front of the prefabricated cabin body is open, the front of the rest cabin body is provided with a panel, the panel is provided with a door opening, the upper part and the lower part of the door opening are respectively provided with a horizontal sliding rail, and the rest cabin further comprises a sliding door

Sliding pins for connecting the sliding door in the horizontal sliding rail are respectively arranged above and below the sliding door, and a liquid crystal display module is arranged on the sliding door;

the panel is provided with an electric lock unit which comprises a locking mechanism and a sliding door position sensor,

the first signal output end of the control unit is connected to the signal input end of the liquid crystal display module, the trigger signal of the sliding door position sensor is used for outputting the trigger signal to the control unit, the control end of the control unit is connected to the controlled end of the locking mechanism, and the controller is used for displaying a corresponding graphical identification code on the liquid crystal display module and controlling the locking mechanism to be unlocked or locked according to a control instruction of the background server.

Further, the prefabricated cabin body comprises a left section, a middle section and a right section, the prefabricated cabin body is composed of a rigid framework and a covering plate connected to the rigid framework, a turnover type mirror board table is installed on a back plate of the middle section prefabricated cabin body,

the mirror plate table comprises a connecting plate, a bearing plate, a mirror plate, a pair of sliding support arms and a pair of hinges,

the two ends of the connecting plate are respectively provided with a bolt hole, the two sides of the front surface of the connecting plate are respectively convexly provided with a convex wall, the convex wall is provided with a vertical slideway,

the upper part of the front surface of the bearing plate is inwards sunken to form an accommodating groove for accommodating the mirror plate, a hinge avoiding long hole which is horizontally arranged and two sliding support arm avoiding long holes which are vertically arranged below two ends of the hinge avoiding long hole respectively are arranged below the accommodating groove, when the front surface of the connecting plate is connected to the back surface of the bearing plate, the two convex walls are respectively positioned in the sliding support arm avoiding long holes,

the front surface of the mirror plate is provided with a lens, the back surface of the mirror plate is provided with a magnetic block,

the pair of sliding support arms are respectively positioned at two sides of the mirror plate, the top ends of the sliding support arms are hinged to the side faces of the mirror plate, sliding columns are convexly arranged at the bottom ends of the outer side faces of the sliding support arms, and the sliding columns are assembled in sliding ways on the convex walls.

Further, the heavy-current load comprises a liquid crystal display television, a top illuminating lamp and a top exhaust fan;

and the strong current load, the weak current load and the power supply management module are all pre-installed on the prefabricated cabin body.

The utility model has the advantages that:

the utility model provides a multistage concatenation formula sharing rest cabin adopts the modular design, installs at the scene. And only all modules are produced in a factory without being assembled, so that the production efficiency is effectively improved. And the wires are pre-arranged, and the plug-in type design is adopted among the wires, so that the difficulty of on-site wiring and the requirements on the relative qualification of operators can be greatly reduced. In addition, during transportation, a transportation unit can transport enough modules, so that the transportation efficiency is fully improved, and the modular design is favorable for disassembling and transferring the shared rest cabin.

Drawings

The multi-section splicing type shared rest cabin of the utility model is further explained with the attached drawings.

Fig. 1 is a schematic structural view of a three-dimensional view angle of the front side of a multi-segment split shared rest cabin of the utility model;

fig. 2 is a schematic structural view of a three-dimensional view angle of the back of the multi-segment split shared rest cabin of the utility model;

FIG. 3 is an exploded view of the rest compartment body in the embodiment;

FIG. 4 is a schematic structural diagram of a right prefabricated cabin;

FIG. 5 is a schematic structural diagram of a left-section prefabricated cabin body skeleton;

FIG. 6 is a schematic view of the structure of the back side of the prefabricated cabin after splicing;

FIG. 7 is a schematic structural diagram of the assembled prefabricated cabin after a middle decorative plate is installed on the back surface of the assembled prefabricated cabin;

FIG. 8 is a schematic structural view of a panel and a slide rail;

FIG. 9 is a schematic view of the structure of the sliding door mounted on the sliding track;

FIG. 10 is a schematic view of the structure of the door opening and the installation position of the electric lock unit;

FIG. 11 is an enlarged view of portion A of FIG. 10;

FIG. 12 is an exploded view of the structure of the panel and the sliding door;

FIG. 13 is a top view of the structure of the prefabricated cabin;

FIG. 14 is a sectional view of the structure taken along line A-A in FIG. 12;

FIG. 15 is a front view of the mirror table;

FIG. 16 is a schematic view of the back structure of the mirror table;

FIG. 17 is a front view of the mirror table;

FIG. 18 is a sectional view of the structure taken along line B-B in FIG. 16;

FIG. 19 is an exploded view of the structure of the mirror table;

FIG. 20 is a schematic view of a mirror plate table in a flipped state;

fig. 21 is the utility model discloses the mounting structure sketch map of well multistage concatenation formula sharing rest cabin top ventilating fan and light.

Detailed Description

Examples

As shown in fig. 1-7, the utility model provides a multi-section splicing type shared rest cabin, including rest cabin body 1, heavy current load, light current load, power management module 104 and a plurality of wires (not shown in the wire drawing) that are connected to heavy current load and/or light current load respectively.

The rest cabin body 1 comprises a plurality of sections of prefabricated cabin bodies which are spliced in sequence. The rest cabin body 1 in this embodiment includes a left prefabricated cabin 101, a middle prefabricated cabin 102 and a right prefabricated cabin 103. Each prefabricated cabin is composed of a rigid framework 901 and a cover plate 902 connected to the rigid framework 901. In this embodiment, as shown in fig. 21, a top exhaust fan 903 and a top illumination lamp 904 are installed on the top wall of the middle prefabricated cabin 102. The liquid crystal television 905 is installed in the right prefabricated cabin 103. The control unit and the network communication module are both installed on the back of the middle prefabricated cabin body 102. The back of the rest cabin body 1 is connected with a back decoration plate 906, the upper end and the lower end of the back decoration plate 906 are bent to form radians, a space is reserved between the back decoration plate 906 and the back of the rest cabin body 1 after the back decoration plate 906 is connected, the space can be used for wiring or containing a power management module 104, a control unit, a network communication module and the like, an access window 9061 is arranged on the back decoration plate 906 corresponding to the back of the middle prefabricated cabin body 102, and the position of the access window 9061 corresponds to the installation position of a weak current load and the power management module 104. A circle of arc-shaped decorative plate 907 is connected to the front edge of the rest cabin body 1. The spliced prefabricated cabin body is provided with a space for installing a rest bed/chair (not shown in the figure).

The heavy electric loads in this embodiment include a liquid crystal television 905, a head light 904, and a head exhaust fan 903. The weak current load comprises a control unit, a network communication module and an electric lock unit 105, wherein the control unit is connected to a remote background server through the network communication module. The strong current load, the weak current load and the power management module 104 are all pre-installed on each prefabricated cabin.

The plurality of wires comprise a strong current wire for supplying 220v, and a weak current wire for supplying network signals, control signals, power demand of the control unit and the like. Each wire is laid and fixed on the rest cabin body 1, when the wires need to be laid on the prefabricated cabin bodies of different sections, the parts of the wires corresponding to the prefabricated cabin bodies of the different sections are divided, and each divided section of wire is still laid on the prefabricated cabin bodies of the different sections independently and correspondingly according to the laying scheme of the original whole wire. The butt joint of adjacent section wire is provided with the public female plug that is used for the grafting respectively, and every wire of being cut apart into the multistage can switch on the reduction through the grafting of public female plug. This approach to break up the whole into parts facilitates modular production and transportation.

As shown in fig. 8-14, the front surfaces of the left prefabricated cabin 101, the middle prefabricated cabin 102 and the right prefabricated cabin 103 are open, the front surface of the rest cabin body 1 formed by splicing the prefabricated cabins is provided with a panel 106, a door opening 601 is formed in the panel 106, a horizontal sliding rail 602 is respectively arranged above and below the door opening 601, and the horizontal sliding rail 602 is hidden in the arc-shaped decorative plate 907. The sliding door is characterized by further comprising a sliding door 107, and sliding feet for connecting the sliding door 107 in the horizontal sliding rail 602 are respectively arranged above and below the sliding door 107.

The sliding door 107 includes a door panel 701, a door frame 702, and a transparent cover 703. The door plate 701 is provided with a horizontal slide 711, the panel 106 is provided with a limiting tenon 603, and the limiting tenon 603 and the horizontal slide 711 form sliding fit. The middle of the door panel 701 is provided with a liquid crystal display module 712, the door frame 702 is connected to the front surface of the door panel 701, the door frame 702 is provided with a liquid crystal display module avoiding groove 721, and the transparent cover plate 703 covers the door frame 702 and protects the liquid crystal display module 712 therein. In the present embodiment, it is preferable that: a camera module 722 is also provided on the door frame 702.

The front panel 106 is provided with an electric lock unit 105, the electric lock unit 105 includes a lock mechanism 501 and a sliding door position sensor 502, and the electric lock unit 105 is located at the end position where the movement of the sliding door 107 can reach. In this embodiment, the locking mechanism 501 is an electromagnet device, an armature is disposed at a corresponding position on the sliding door 107, and the position sensor 502 of the sliding door 107 is a striker-type trigger switch. When the sliding door 107 moves to a preset position, the striker type trigger switch is triggered, the trigger switch gives out relevant signals to the control unit, and the control unit controls the electromagnet device to be electrified to generate suction force and suck the armature to form locking limit on the door.

A first signal output end of the control unit is connected to a signal input end of the liquid crystal display module 712, a trigger signal of the position sensor 502 of the sliding door 107 is used for outputting to the control unit, a control end of the control unit is connected to a controlled end of the locking mechanism 501, and the controller is used for displaying a corresponding pattern identification code on the liquid crystal display module 712 according to a control instruction of the background server and controlling the locking or unlocking of the locking mechanism 501.

As shown in fig. 15 to 19, in order to increase space utilization and facilitate users to arrange instruments or place articles, it is preferable in this embodiment that: the back plate of the middle prefabricated cabin 102 is provided with a turnover type mirror plate table 201, and the mirror plate table comprises a connecting plate 211, a bearing plate 212, a mirror plate 213, a pair of sliding support arms 214 and a pair of hinges 215.

Wherein, the two ends of the connecting plate 211 are respectively provided with bolt holes for connecting when the connecting plate 211 is fixed on the back plate of the middle prefabricated cabin 102. Protruding walls 2111 are formed on two sides of the front face of the connecting plate 211 in a protruding mode, and vertical sliding ways 2112 are arranged on the protruding walls 2111.

The upper portion of the front surface of the bearing plate 212 is recessed inwards to form a receiving groove 2121 for receiving the mirror plate 213, a hinge avoiding long hole 2122 horizontally arranged and two sliding support arm avoiding long holes 2123 vertically arranged below two ends of the hinge avoiding long hole 2122 are formed below the receiving groove 2121, when the front surface of the connecting plate 211 is connected to the back surface of the bearing plate 212, the two convex walls 2111 are respectively located in the sliding support arm avoiding long holes 2123, and the width of the sliding support arm avoiding long holes 2123 is greater than the sum of the thicknesses of the convex walls 2111 and the sliding support arms 214. A pair of sliding support arms 214 are respectively located at both sides of the mirror plate 213, the top ends of the sliding support arms 214 are hinged to the side surfaces of the mirror plate 213, the bottom ends of the outer side surfaces of the sliding support arms 214 are convexly provided with sliding columns 2141, and the sliding columns 2141 are assembled in the vertical slideways 2112. When the mirror plate 213 is vertically accommodated in the accommodating groove 2121, the slide support arm 214 is also vertically accommodated in the slide support arm escape long hole 2123.

The mirror plate 213 has a mirror 2131 on its front surface and a magnet (not shown) on its back surface. In order to cooperate with the magnetic block, the whole carrier plate 212 may be made of a magnetic material, or a magnetic area may be disposed at a position of the carrier plate 212 opposite to the magnetic block, so as to allow the magnetic block to catch and limit the mirror plate 213 to automatically turn downward and open under the action of gravity.

As shown in FIG. 20, when the mirror plate 213 is manually flipped open, the bottom ends of the sliding support arms 214 slide down the vertical runners 2112 and form a triangular support for the mirror plate 213.

The utility model discloses a not be limited to above-mentioned embodiment, the technical scheme of above-mentioned each embodiment can the cross combination form new technical scheme each other, and all adopt the technical scheme who equates the replacement formation in addition all to fall into the utility model discloses the required protection within range.

Claims (4)

1. The utility model provides a rest cabin is shared to multistage concatenation formula, includes rest cabin body, forceful electric power load, light current load, power management module and is connected to respectively a plurality of wires of forceful electric power load and/or light current load which characterized in that:

the rest cabin body comprises a plurality of sections of prefabricated cabin bodies which are sequentially spliced;

the plurality of wires are laid and fixed on the rest cabin body, when all or part of the plurality of wires need to be laid on prefabricated cabin bodies in different sections, the part of the wire corresponding to the prefabricated cabin bodies in the different sections is divided, each divided section of wire is still laid on the prefabricated cabin bodies in the different sections according to the original laying scheme of the whole wire, male and female plugs for plugging are respectively arranged at the butt joint parts of the adjacent sections of wire, and each divided section of wire can be conducted and restored through plugging of the male and female plugs.

2. The multi-segment splicing type shared rest cabin of claim 1, wherein: the weak current load comprises a control unit and a network communication module, and the control unit is connected to a remote background server through the network communication module;

the front of the prefabricated cabin body is open, the front of the rest cabin body is provided with a panel, the panel is provided with a door opening, the upper part and the lower part of the door opening are respectively provided with a horizontal sliding rail, and the rest cabin further comprises a sliding door

Sliding pins for connecting the sliding door in the horizontal sliding rail are respectively arranged above and below the sliding door, and a liquid crystal display module is arranged on the sliding door;

the panel is provided with an electric lock unit which comprises a locking mechanism and a sliding door position sensor,

the first signal output end of the control unit is connected to the signal input end of the liquid crystal display module, the trigger signal of the sliding door position sensor is used for outputting the trigger signal to the control unit, the control end of the control unit is connected to the controlled end of the locking mechanism, and the control unit is used for displaying a corresponding graphical identification code on the liquid crystal display module and controlling the locking mechanism to be unlocked or locked according to a control instruction of a background server.

3. The multi-segment splicing type shared rest cabin of claim 1, wherein:

the prefabricated cabin body comprises a left prefabricated cabin body, a middle prefabricated cabin body and a right prefabricated cabin body, the prefabricated cabin bodies are respectively composed of a rigid framework and a covering plate connected to the rigid framework, a turnover type mirror board table is mounted on a back plate of the middle prefabricated cabin body,

the mirror plate table comprises a connecting plate, a bearing plate, a mirror plate, a pair of sliding support arms and a pair of hinges,

the two ends of the connecting plate are respectively provided with a bolt hole, the two sides of the front surface of the connecting plate are respectively convexly provided with a convex wall, the convex wall is provided with a vertical slideway,

the upper part of the front surface of the bearing plate is inwards sunken to form an accommodating groove for accommodating the mirror plate, a hinge avoiding long hole which is horizontally arranged and two sliding support arm avoiding long holes which are vertically arranged below two ends of the hinge avoiding long hole respectively are arranged below the accommodating groove, when the front surface of the connecting plate is connected to the back surface of the bearing plate, the two convex walls are respectively positioned in the sliding support arm avoiding long holes,

the front surface of the mirror plate is provided with a lens, the back surface of the mirror plate is provided with a magnetic block,

the pair of sliding support arms are respectively positioned at two sides of the mirror plate, the top ends of the sliding support arms are hinged to the side faces of the mirror plate, sliding columns are convexly arranged at the bottom ends of the outer side faces of the sliding support arms, and the sliding columns are assembled in sliding ways on the convex walls.

4. The multi-segment splicing type shared rest cabin of claim 1, wherein: the strong electric load comprises a liquid crystal display television, a top illuminating lamp and a top exhaust fan;

and the strong current load, the weak current load and the power supply management module are all pre-installed on the prefabricated cabin body.

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