CN210313363U - Layered shell structure suitable for carrying forklift - Google Patents

Abstract

The utility model discloses a layer-stepping shell structure suitable for transport fork truck, include: a housing; the shell is provided with an installation space; the shell is also provided with a first clapboard; a first partition installed into the installation space and dividing the installation space into a first space layer and a second space layer; the shell is also provided with two second partition plates; two second partitions are mounted to the first spatial layer and divide the first spatial layer into two driving spaces and a power supply mounting space; the power supply installation space is positioned between the two driving spaces; the shell is also provided with a third clapboard; a third partition installed to the second space layer and dividing the second space layer into a branching space and a unit space; the unit space is defined to include a camera installation space for installing a camera and a controller installation space for installing a controller. The layered shell structure suitable for carrying the forklift is high in space utilization rate and good in support performance and heat insulation performance.

Description

Layered shell structure suitable for carrying forklift

Technical Field

The utility model relates to a layer-stepping shell structure suitable for transport fork truck.

Background

The inside mode that adopts the modularization installation of traditional transport fork truck, the module mainly through panel beating mounting or screw lug fixation on the shell body. The inner space of the outer shell is completely communicated, and an effective isolation mode is lacked between the modules. The controller is large in size, is limited by the size of the controller and can only be arranged above the battery. The controller is lack of effective support and poor in stability due to the installation mode, and meanwhile, the controller is installed above the battery with huge heat productivity and is seriously influenced by high temperature.

SUMMERY OF THE UTILITY MODEL

The utility model provides a layer-stepping shell structure suitable for transport fork truck adopts following technical scheme:

a tiered housing structure suitable for use with a handling forklift, comprising: a housing; the shell is provided with an installation space; the shell is also provided with a first clapboard; a first partition installed into the installation space and dividing the installation space into a first space layer and a second space layer; the shell is also provided with two second partition plates; two second partitions are mounted to the first space layer and divide the first space layer into two driving spaces for mounting driving wheels and a power supply mounting space for mounting a power supply; the power supply installation space is positioned between the two driving spaces; the shell is also provided with a third clapboard; a third partition installed to the second space layer and dividing the second space layer into a branching space for branching and a unit space for installing a camera and a controller; the unit space is defined to include a camera installation space for installing a camera and a controller installation space for installing a controller; the camera installation space is communicated with the controller installation space and is positioned between the branching space and the controller installation space.

Further, the first spatial layer is located below the second spatial layer in a vertical direction.

Further, the height of the first spatial layer in the vertical direction is greater than the height of the second spatial layer in the vertical direction.

Further, the sum of the spatial volumes of the two driving spaces is smaller than the spatial volume of the power supply installation space.

Further, the spatial volume of the unit space is larger than that of the power supply installation space.

Further, the width of the branching space in the extending direction of the first partition is larger than the width of the driving space in the extending direction of the first partition.

Further, a width of the unit space in the extending direction of the first partition is larger than a width of the power supply installation space in the extending direction of the first partition.

The utility model discloses an useful part lies in that the layer-stepping shell structure's that is applicable to transport fork truck that provides space utilization is higher, can rationally install transport fork truck's electronic components and have better thermal-insulated and heat dispersion. The layered shell structure suitable for the carrying forklift supports the controller through the first partition plate, and the structural stability is high.

Drawings

Fig. 1 is a schematic diagram of a layered shell structure suitable for a carrying forklift of the present invention.

The layered shell structure 10 suitable for a transport forklift includes a shell 11, an installation space 111, a first partition 12, a second partition 13, a third partition 14, a first space layer 15, a driving space 151, a power supply installation space 152, a second space layer 16, a branching space 161, a unit space 162, a camera installation space 163, and a controller installation space 164.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1, a layered shell 11 structure 10 suitable for a handling forklift includes: a housing 11. The housing 11 is formed with a mounting space 111. The drive wheels, power supply, controller, and camera of the transport forklift are all mounted in the mounting space 111. The control lines of the transport forklift are routed and branched in the installation space 111.

Specifically, the housing 11 is also provided with a first partition 12. The first partition 12 is installed into the installation space 111 and partitions the installation space 111 into a first spatial layer 15 and a second spatial layer 16. The housing 11 is further provided with two second partitions 13. The two second partitions 13 are mounted to the first spatial layer 15 and divide the first spatial layer 15 into two driving spaces 151 and a power supply mounting space 152. The driving space 151 is used to mount a driving wheel. The power supply installation space 152 is used for installing a power supply. The power supply installation space 152 is located between the two driving spaces 151. The housing 11 is also provided with a third partition 14. The third partition 14 is mounted to the second spatial layer 16 and partitions the second spatial layer 16 into a branching space 161 and a unit space 162. The branching space 161 is for branching. The unit space 162 is used to mount the camera and the controller. Further, the unit space 162 is defined to include a camera installation space 163 and a controller installation space 164. The camera mounting space 163 is used to mount a camera. The controller installation space 164 is used to install the controller. The camera mounting space 163 communicates with the controller mounting space 164 and is located between the branching space 161 and the controller mounting space 164.

Specifically, the first partition plate 12, the second partition plate 13, and the third partition plate 14 are all sheet metal members. According to actual needs, the installation space 111 is reasonably divided by the first partition plate 12, the second partition plate 13 and the third partition plate 14, and optimal utilization of the installation space 111 and reasonable flow guiding of heat are achieved. The installation space 111 is divided into a driving space 151, a power supply installation space 152, a controller installation space 164, a camera installation space 163, and a branching space 161. The power supply having a large heat generation amount is disposed in the power supply installation space 152, and the controller having a severe performance degradation due to the high temperature is disposed in the controller installation space 164. Therefore, the heat generated by the power supply can be prevented from being directly transferred to the controller, so that the controller is prevented from being damaged. Meanwhile, each space can be respectively provided with different heat dissipation schemes. After the installation space 111 is divided, due to the arrangement of the first partition plate 12, the second partition plate 13 and the third partition plate 14, a plurality of fixed supporting surfaces are added, more modules can be installed while the controller is well supported, and the stability of the module layout and installation structure can be better realized by utilizing the limited space.

As a specific embodiment, the first spatial layer 15 is located below the second spatial layer 16 in a vertical direction. The driving wheel and the power supply are arranged below the controller and the camera, and the functional requirements of the forklift for carrying are met.

As a specific embodiment, the height of the first spatial layer 15 in the vertical direction is greater than the height of the second spatial layer 16 in the vertical direction. The high height of the first space layer 15 is advantageous for heat dissipation of the power supply.

As a specific embodiment, the sum of the spatial volumes of the two driving spaces 151 is smaller than the spatial volume of the power supply installation space 152.

As a specific embodiment, the spatial volume of the unit space 162 is greater than the spatial volume of the power supply installation space 152.

In a specific embodiment, the width of the branching space 161 in the extending direction of the first partition 12 is larger than the width of the driving space 151 in the extending direction of the first partition 12.

As a specific embodiment, the width of the unit space 162 in the extending direction of the first partition 12 is greater than the width of the power supply installation space 152 in the extending direction of the first partition 12.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It should be understood by those skilled in the art that the above embodiments do not limit the present invention in any way, and all technical solutions obtained by adopting equivalent replacement or equivalent transformation fall within the protection scope of the present invention.

Claims (7)

1. A tiered housing structure suitable for use with a handling forklift, comprising: a housing; the housing is formed with an installation space; the device is characterized in that the shell is also provided with a first clapboard; the first partition is installed into the installation space and divides the installation space into a first spatial layer and a second spatial layer; the shell is also provided with two second partition plates; two second partitions are mounted to the first space layer and divide the first space layer into two driving spaces for mounting driving wheels and a power supply mounting space for mounting a power supply; the power supply installation space is positioned between the two driving spaces; the shell is also provided with a third clapboard; the third partition is mounted to the second spatial layer and partitions the second spatial layer into a branching space for branching and a unit space for mounting a camera and a controller; the unit space is defined to include a camera installation space for installing a camera and a controller installation space for installing a controller; the camera installation space is communicated with the controller installation space and is positioned between the branching space and the controller installation space.

2. The tiered shell structure for a handling forklift truck as recited in claim 1,

the first spatial layer is located below the second spatial layer in a vertical direction.

3. The tiered shell structure for a handling forklift truck as recited in claim 2,

the height of the first spatial layer in the vertical direction is greater than the height of the second spatial layer in the vertical direction.

4. The tiered shell structure for a handling forklift truck as recited in claim 3,

the sum of the space volumes of the two driving spaces is smaller than the space volume of the power supply installation space.

5. The tiered shell structure for a handling forklift truck as recited in claim 4,

the spatial volume of the unit space is larger than the spatial volume of the power supply installation space.

6. The tiered shell structure for a handling forklift truck as recited in claim 5,

the width of the branching space in the extending direction of the first partition is larger than the width of the driving space in the extending direction of the first partition.

7. The tiered shell structure for a handling forklift truck as recited in claim 6,

the width of the unit space in the extending direction of the first partition is larger than the width of the power supply installation space in the extending direction of the first partition.

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