CN220359044U - Combined rack type charging and inverting integrated machine - Google Patents

Abstract

The utility model belongs to the technical field of charging inverters, and particularly relates to a combined rack-mounted charging and inverting integrated machine, which comprises a rack-mounted charging and inverting integrated machine shell and a combined mechanism; the frame type charging and inverting integrated machine shell is of a rectangular structure, the top of the frame type charging and inverting integrated machine shell is provided with an assembly groove, the combination mechanism is movably clamped on two side walls of the frame type charging and inverting integrated machine shell, and one side wall of the frame type charging and inverting integrated machine shell is provided with a cable interface, an alternating current input port and an alternating current output port; the assembly groove is used for movably connecting the mounting ring, the linkage rod and the pull buckle, so that the pull buckle can conveniently move the rack type charging and inverting integrated machine while saving the strength, and the effect of being embedded in the assembly groove is achieved, the effect of hiding and mounting the rack is achieved, and the charging and inverting integrated machine can synchronously complete various combination modes.

Description

Combined rack type charging and inverting integrated machine

Technical Field

The utility model belongs to the technical field of charging inverters, and particularly relates to a combined rack type charging and inverting integrated machine.

Background

The inverter converts direct current electric energy (battery, accumulator) into alternating current (generally 220V,0Hz sine wave), which is composed of an inverter bridge, a control logic and a filter circuit, and is widely applicable to air conditioners, home theatres, electric grinding wheels, electric tools, sewing machines, DVDs, VCDs, computers, televisions, washing machines, smoke exhaust fans, refrigerators, video recorders, massagers, fans, illumination and the like.

Through searching, in the prior art, chinese patent application number CN201420408791.7 applies for the following days: 2017-8-25 discloses a frame-type charging inversion all-in-one machine shell which is cube-shaped and comprises an upper surface, a lower surface and four peripheral surfaces, wherein the upper surface and the lower surface are parallel to each other, the four peripheral surfaces are arranged between the upper surface and the lower surface in a surrounding mode, an alternating current input port, an alternating current output port, a cable interface and a power switch are arranged on any peripheral surface, mounting holes are respectively formed in two ends of the peripheral surface, a rotatable pull buckle is arranged on each mounting Kong Zhongan, and the pull buckle is provided with a through hole for inserting a finger, and the gravity center of the pull buckle is located outside the frame-type charging inversion all-in-one machine shell. According to the frame type charging and inverting integrated machine shell, the mounting holes are formed in the peripheral surface, and the rotatable pull buckles with the gravity centers outside the frame type charging and inverting integrated machine shell are arranged in the mounting holes, so that the pull buckles are enabled to be out of the peripheral surface range, when the frame type charging and inverting integrated machine shell is used, the pull buckles can be rotated conveniently, fingers can penetrate through the through holes of the pull buckles, and therefore the frame type charging and inverting integrated machine can be moved conveniently, and the strength is saved.

The device still has the following drawbacks: although the pulling buckle can be conveniently rotated and fingers can pass through the through holes of the pulling buckle, the rack type charging and inverting integrated machine can be conveniently moved, and the strength is saved, the plurality of charging and inverting integrated machines are required to be synchronously installed according to the continuous change of the requirements of the use environment, the plurality of charging and inverting integrated machines cannot be synchronously installed in the existing installation mode, and inconvenience is brought to operators during installation.

Disclosure of Invention

Aiming at the problems, the utility model provides a combined rack-mounted charging and inverting integrated machine, which comprises a rack-mounted charging and inverting integrated machine shell and a combined mechanism;

the frame type charging and inverting integrated machine shell is of a rectangular structure, the top of the frame type charging and inverting integrated machine shell is provided with an assembly groove, the combination mechanism is movably clamped on two side walls of the frame type charging and inverting integrated machine shell, and one side wall of the frame type charging and inverting integrated machine shell is provided with a cable interface, an alternating current input port and an alternating current output port;

the combined mechanism comprises a first frame part and a second frame part; the structure, the shape of first frame portion and second frame portion are the same, two sets of first erection columns of fixedly connected with between the adjacent lateral wall of first frame portion and second frame portion, still fixedly connected with two sets of second erection columns between the adjacent lateral wall of first frame portion and second frame portion, two sets of first erection column and two sets of the second erection column all distributes in the corner of first frame portion, two sets of rotate on the second erection column and be connected with the collar, two sets of fixedly connected with gangbar on the collar, just the tip fixedly connected with of gangbar draws the knot, second erection column, collar, gangbar and the equal rotation connection of drawing the knot are at the inner wall of assembly groove.

Further, the first rack part comprises a rack shell, a first limiting plate, a second limiting plate, a lower rack unit and an upper rack unit;

the frame casing is open structure, just the adjustment tank has been seted up on the surface of frame casing, the hollow smooth chamber of intercommunication each other has been seted up with the low end in the top of adjustment tank, just hollow smooth chamber and adjustment tank intercommunication each other.

Further, the first limiting plate is fixedly connected to the top of the frame shell, and the second limiting plate is fixedly connected to the bottom of the frame shell.

Further, one side of the bottom of the first limiting plate is fixedly connected with a first micro motor, the output end of the first micro motor is in transmission connection with a first screw rod, one end of the first screw rod, which is far away from the output end of the first micro motor, is rotationally connected to the top of the second limiting plate, the first screw rod is in threaded connection with the lower frame unit, and the lower frame unit is in sliding connection with the inner wall of the hollow sliding cavity.

Further, a second micro motor is fixedly connected to one side of the top of the second limiting plate, and a second screw rod is connected to the output end of the second micro motor in a transmission mode.

Further, one end of the second screw rod, which is far away from the output end of the second micro motor, is rotationally connected to the bottom of the first limiting plate, the second screw rod is in threaded connection with the lower frame unit, and the lower frame unit is in sliding connection with the inner wall of the hollow sliding cavity.

Further, the lower frame unit comprises a first linkage plate; a first linkage block is fixedly connected to one side wall of the first linkage plate and is in threaded connection with the first screw rod, and a plurality of groups of locking holes are distributed on the surface of the first linkage block in a rectangular array mode.

Further, the upper frame unit comprises a second linkage plate; a side wall fixedly connected with second linkage piece of second linkage board, just second linkage piece and second lead screw threaded connection, a plurality of groups of gas springs are installed to the surface embedding of second linkage board, and a plurality of groups gas springs are rectangular array setting, and a plurality of groups gas spring's output is all transmitted and is connected with powerful magnetic path, and a plurality of groups powerful magnetic path is all swing adsorption and is connected in the locking downthehole.

The beneficial effects of the utility model are as follows:

1. the assembly groove is used for movably connecting the mounting ring, the linkage rod and the pull buckle, so that the pull buckle can conveniently move the rack type charging and inverting integrated machine while saving the strength, and the effect of being embedded in the assembly groove is achieved, the effect of hiding and mounting the rack is achieved, and the charging and inverting integrated machine can synchronously complete various combination modes.

2. Through the structure, the size of first frame portion and second frame portion the same, can the movable fit connect the both sides wall at frame type charging inversion all-in-one shell to through the user demand, start first micro motor and second micro motor respectively, when first micro motor is rotatory, can remove lower frame unit to the adjustment inslot, when the second micro motor is rotatory, can remove upper frame unit to the adjustment inslot, be used for switching the mounting means of frame type charging inversion all-in-one shell both sides wall.

3. When the lower rack units of the rack-mounted charging inversion integrated machine shell move into the adjusting groove, the other rack units of the rack-mounted charging inversion integrated machine shell move into the adjusting groove, the locking holes in the lower rack units can be connected with the powerful magnetic blocks on the second linkage plate in a mutually-sucking manner, the function of quickly adsorbing and splicing the two groups of rack-mounted charging inversion integrated machine shells is achieved, and the quick combined locking efficiency of the two groups of rack-mounted charging inversion integrated machine shells is improved.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model. The objectives and other advantages of the utility model may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 shows a schematic structural diagram of a charging and inverting integrated machine according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram showing the structure of a combination mechanism according to an embodiment of the present utility model;

FIG. 3 is a schematic view showing the structure of a first frame part according to an embodiment of the present utility model;

FIG. 4 is a schematic view of the structure of a lower rack unit according to an embodiment of the present utility model;

fig. 5 shows a schematic structural diagram of a rack unit according to an embodiment of the present utility model.

In the figure: 1. frame type charging and inversion integrated machine shell; 2. an assembly groove; 3. a combination mechanism; 31. a first frame portion; 311. a housing of the frame; 312. an adjustment tank; 313. a hollow sliding cavity; 314. a first limiting plate; 315. a second limiting plate; 316. a first micro motor; 317. a first screw rod; 318. a lower rack unit; 3181. a first linkage plate; 3182. a first linkage block; 3183. a locking hole; 319. a second micro motor; 3110. a second screw rod; 3111. an upper rack unit; 31111. a second linkage plate; 31112. a second linkage block; 31113. a gas spring; 31114. a strong magnetic block; 32. a second frame part; 33. a first mounting post; 34. a second mounting post; 35. a mounting ring; 36. a linkage rod; 37. pulling buckle; 4. a cable interface; 5. an ac input port; 6. an ac outlet.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The embodiment of the utility model provides a combined rack-mounted charging and inverting integrated machine, which comprises a rack-mounted charging and inverting integrated machine shell 1 and a combined mechanism 3; as illustrated by way of example in fig. 1.

The frame-type charging inversion integrated machine shell 1 is of a rectangular structure, the top of the frame-type charging inversion integrated machine shell 1 is provided with an assembly groove 2, the combination mechanism 3 is movably clamped on two side walls of the frame-type charging inversion integrated machine shell 1, and one side wall of the frame-type charging inversion integrated machine shell 1 is provided with a cable interface 4, an alternating current input port 5 and an alternating current output port 6.

The combination mechanism 3 comprises a first frame part 31 and a second frame part 32; as illustrated by way of example in fig. 2.

The structure and the shape of the first frame part 31 and the second frame part 32 are the same, two groups of first mounting columns 33 are fixedly connected between two adjacent side walls of the first frame part 31 and the second frame part 32, two groups of second mounting columns 34 are fixedly connected between two adjacent side walls of the first frame part 31 and the second frame part 32, the first mounting columns 33 and the second mounting columns 34 are distributed at the corners of the first frame part 31, the second mounting columns 34 are rotatably connected with mounting rings 35, the mounting rings 35 are fixedly connected with linkage rods 36, the end parts of the linkage rods 36 are fixedly connected with pull buckles 37, and the second mounting columns 34, the mounting rings 35, the linkage rods 36 and the pull buckles 37 are rotatably connected to the inner walls of the assembly grooves 2.

The first frame part 31 includes a frame housing 311, a first limiting plate 314, a second limiting plate 315, a lower frame unit 318, and an upper frame unit 3111; as illustrated by way of example in fig. 3.

The frame shell 311 is of an open structure, an adjusting groove 312 is formed in the surface of the frame shell 311, a hollow sliding cavity 313 which is communicated with each other is formed in the top and the lower end of the adjusting groove 312, the hollow sliding cavity 313 is communicated with the adjusting groove 312, a first limiting plate 314 is fixedly connected to the top of the frame shell 311, a second limiting plate 315 is fixedly connected to the bottom of the frame shell 311, a first micro motor 316 is fixedly connected to one side of the bottom of the first limiting plate 314, a first screw rod 317 is connected to the output end of the first micro motor 316 in a transmission manner, one end of the first screw rod 317, far away from the output end of the first micro motor 316, is connected to the top of the second limiting plate 315 in a rotating manner, the first screw rod 317 is connected with a lower frame unit 318 in a threaded manner, the lower frame unit 318 is connected to the inner wall of the hollow sliding cavity 313 in a sliding manner, a second micro motor 319 is fixedly connected to one side of the top of the second limiting plate 315, the output end of the second micro motor 319 is connected to a second screw rod 3110 in a transmission manner, the second screw rod 3110 is connected to the output end of the second screw rod 319, and the output end of the second screw rod 319 is far away from the first frame unit 318 in a rotating manner, and the lower frame unit is connected to the inner wall of the hollow sliding cavity 313 in a threaded manner.

The lower housing unit 318 includes a first linkage plate 3181; as illustrated by way of example in fig. 4.

A side wall of the first linkage plate 3181 is fixedly connected with a first linkage block 3182, the first linkage block 3182 is in threaded connection with the first screw rod 317, and a plurality of groups of locking holes 3183 are distributed on the surface of the first linkage block 3182 in a rectangular array mode.

The upper housing unit 3111 includes a second linkage plate 31111; as illustrated by way of example in fig. 5.

A second linkage block 31112 is fixedly connected to a side wall of the second linkage plate 31111, the second linkage block 31112 is in threaded connection with the second screw rod 3110, a plurality of groups of gas springs 31113 are embedded and mounted on the surface of the second linkage plate 31111, the gas springs 31113 are arranged in a rectangular array, the output ends of the gas springs 31113 are in transmission connection with powerful magnetic blocks 31114, and the powerful magnetic blocks 31114 are in movable adsorption connection in the locking holes 3183.

Specifically, the assembly groove 2 is used for movably connecting the mounting ring 35, the linkage rod 36 and the pull buckle 37, so that the pull buckle 37 can conveniently move the rack type charging and inverting integrated machine, the strength is saved, and meanwhile, the assembly groove 2 can be embedded and mounted, so that the hidden mounting effect of the rack is achieved;

the first frame portion 31 and the second frame portion 32 have the same structure and size, and can be movably attached to and connected to two side walls of the frame-type charging and inverting integrated machine housing 1, and respectively start the first micro motor 316 and the second micro motor 319 according to the use requirement, when the first micro motor 316 rotates, the lower frame unit 318 can be moved into the adjusting slot 312, and when the second micro motor 319 rotates, the upper frame unit 3111 can be moved into the adjusting slot 312 for switching the mounting modes of the two side walls of the frame-type charging and inverting integrated machine housing 1;

when the lower frame unit 318 of the frame type charging and inverting integrated machine housing 1 moves into the adjusting groove 312, and the upper frame unit 3111 of the frame type charging and inverting integrated machine housing 1 moves into the adjusting groove 312, the locking hole 3183 in the lower frame unit 318 can be connected with the powerful magnet 31114 on the second linkage plate 31111 in a mutually sucking way, so as to be used for quickly adsorbing and splicing the functions of the two frame type charging and inverting integrated machine housings 1.

The working principle of the combined rack type charging and inverting integrated machine provided by the embodiment of the utility model is as follows:

the assembly groove 2 is used for movably connecting the mounting ring 35, the linkage rod 36 and the pull buckle 37, so that the pull buckle 37 can conveniently move the rack type charging and inverting integrated machine, the strength is saved, and meanwhile, the effect of being embedded in the assembly groove 2 is achieved, and the effect of hiding and mounting the rack is achieved;

the first frame part 31 and the second frame part 32 have the same structure and size, can be movably attached to and connected with the two side walls of the frame type charging inversion integrated machine shell 1, and respectively start the first micro motor 316 and the second micro motor 319 according to the use requirement, when the first micro motor 316 rotates, the lower frame unit 318 can be moved into the regulating groove 312, and when the second micro motor 319 rotates, the upper frame unit 3111 can be moved into the regulating groove 312 for switching the mounting mode of the two side walls of the frame type charging inversion integrated machine shell 1;

when the lower frame unit 318 of the frame type charging and inverting integrated machine housing 1 moves into the adjusting groove 312, and the upper frame unit 3111 of the frame type charging and inverting integrated machine housing 1 moves into the adjusting groove 312, the locking hole 3183 in the lower frame unit 318 can be connected with the powerful magnet 31114 on the second linkage plate 31111 in a mutually sucking way, so as to be used for quickly adsorbing and splicing the functions of the two frame type charging and inverting integrated machine housings 1.

Although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (8)

1. A combination rack-mounted charging inversion integrated machine is characterized in that: comprises a rack-mounted charging and inverting integrated machine shell (1) and a combined mechanism (3);

the frame type charging inversion integrated machine shell (1) is of a rectangular structure, an assembly groove (2) is formed in the top of the frame type charging inversion integrated machine shell (1), the combined mechanism (3) is movably clamped on two side walls of the frame type charging inversion integrated machine shell (1), and a cable interface (4), an alternating current input port (5) and an alternating current output port (6) are formed in one side wall of the frame type charging inversion integrated machine shell (1);

the combination mechanism (3) comprises a first frame part (31) and a second frame part (32); the structure, the shape of first frame portion (31) and second frame portion (32) are the same, two sets of first erection column (33) of fixedly connected with between adjacent lateral wall of first frame portion (31) and second frame portion (32), still fixedly connected with two sets of second erection column (34) between adjacent lateral wall of first frame portion (31) and second frame portion (32), two sets of first erection column (33) and two sets of second erection column (34) all distribute in the corner of first frame portion (31), two sets of rotation is connected with collar (35) on second erection column (34), two sets of fixedly connected with gangbar (36) on collar (35), just the tip fixedly connected with of gangbar (36) is drawn knot (37), second erection column (34), collar (35), gangbar (36) and are all rotated and are connected at the inner wall of assembly groove (2).

2. The combined rack-mounted charging and inverting integrated machine according to claim 1, wherein: the first rack part (31) comprises a rack shell (311), a first limiting plate (314), a second limiting plate (315), a lower rack unit (318) and an upper rack unit (3111);

the frame shell (311) is of an open structure, an adjusting groove (312) is formed in the surface of the frame shell (311), a hollow sliding cavity (313) which is mutually communicated is formed in the top and the lower end of the adjusting groove (312), and the hollow sliding cavity (313) is mutually communicated with the adjusting groove (312).

3. The combined rack-mounted charging and inverting integrated machine according to claim 2, wherein: the first limiting plate (314) is fixedly connected to the top of the frame shell (311), and the second limiting plate (315) is fixedly connected to the bottom of the frame shell (311).

4. A combined rack-mounted charging and inverting integrated machine according to claim 3, wherein: first limiting plate (314) bottom one side fixedly connected with first micro motor (316), just the output transmission of first micro motor (316) is connected with first lead screw (317), the one end rotation that first lead screw (317) kept away from first micro motor (316) output is connected at the top of second limiting plate (315), first lead screw (317) and lower frame unit (318) threaded connection, just lower frame unit (318) sliding connection is at the inner wall of hollow smooth chamber (313).

5. The combined rack-mounted charging and inverting integrated machine according to claim 4, wherein: and one side of the top of the second limiting plate (315) is fixedly connected with a second micro motor (319), and the output end of the second micro motor (319) is in transmission connection with a second screw rod (3110).

6. The combined rack-mounted charging and inverting integrated machine according to claim 5, wherein: one end of the second screw rod (3110) far away from the output end of the second micro motor (319) is rotationally connected to the bottom of the first limiting plate (314), the second screw rod (3110) is in threaded connection with the lower frame unit (318), and the lower frame unit (318) is in sliding connection with the inner wall of the hollow sliding cavity (313).

7. The combined rack-mounted charging and inverting integrated machine according to claim 2, wherein: the lower housing unit (318) includes a first linkage plate (3181); a first linkage block (3182) is fixedly connected to one side wall of the first linkage plate (3181), the first linkage block (3182) is in threaded connection with the first screw rod (317), and a plurality of groups of locking holes (3183) are distributed on the surface of the first linkage block (3182) in a rectangular array mode.

8. The combined rack-mounted charging and inverting integrated machine according to claim 2, wherein: the upper frame unit (3111) includes a second linkage plate (31111); a second linkage block (31112) is fixedly connected to one side wall of the second linkage plate (31111), the second linkage block (31112) is in threaded connection with the second screw rod (3110), a plurality of groups of gas springs (31113) are installed on the surface embedding of the second linkage plate (31111), the gas springs (31113) are arranged in a rectangular array, the output ends of the gas springs (31113) are all in transmission connection with powerful magnetic blocks (31114), and the powerful magnetic blocks (31114) are all in movable adsorption connection in the locking holes (3183).