JP5727057B1 - Gravity cast lattice structure of storage battery and its transport system - Google Patents

Abstract

The present invention provides a gravity cast lattice structure of a storage battery and its transportation system that can greatly reduce the cost of raw materials and reduce the loss cost in the manufacturing process to prevent environmental pollution. A gravitational cast lattice structure of a storage battery includes a lattice body. A peripheral frame 11 is formed on the outer edge of the lattice body 1. A lattice grid 12 is formed in the peripheral frame 11. At the upper end of the peripheral frame 11, a hanging bar 13 is provided so as to extend to both sides. At the lower end of the peripheral frame 11, latching rods 14 project from both sides so as to make a pair with the suspension bar 13. A hooking portion 141 is formed at the front end of the hooking rod 14. The hanging bar 13 of another lattice body 1 is hooked on the hooking portion 141. [Selection] Figure 1

Description

  The present invention relates to a gravitation cast grid structure of a storage battery and its transport system, and in particular, the front end and the end of each grid are connected on a belt conveyor, and in the transport movement process between each grid on the belt conveyor. Gravity cast grids for storage batteries that can reduce the cost of raw materials and prevent environmental pollution by reducing the cost of raw materials by preventing the application of pole materials on the belt conveyor because no gaps occur. It relates to the structure and its transport system.

  Various types of lead storage batteries that are commonly seen are storage batteries composed of a positive electrode plate, a negative electrode plate, a separator, a battery stack, an electrolytic solution, a connection terminal, and the like. It can return to the state of and can be used repeatedly.

When manufacturing such an electrode plate of a storage battery, the positive and negative electrode materials are respectively applied on the grid body, and then the positive and negative electrode materials applied on the grid body in a drying step are dried and cured. Please refer to FIG. 7 and FIG. FIG. 7 is a perspective view showing a lattice structure of a conventional storage battery. FIG. 8 is a schematic diagram showing a manufacturing process of a lattice structure of a conventional storage battery.
As shown in FIGS. 7 and 8, the lattice body 3 has a peripheral frame 31. A grid grid 32 is arranged in the peripheral frame 31. At the upper end of the peripheral frame 31, a hanging bar 33 projecting from both sides is projected. When applying the pole material on the grid body 3, the grid body 3 is arranged on the belt conveyor, the pole material is applied to the grid body 3 to be transported on the belt conveyor using a coating device, and the belt conveyor is used. Then, the grid body 3 coated with the pole material is transported to a drying apparatus to perform a drying process, thereby completing the manufacturing process.

  The grids described above can be transported by a belt conveyor and the pole material can be applied by a spraying device. However, if the grids are arranged on the belt conveyor, the grids do not adhere to each grid on the belt conveyor. Since gaps are created between the bodies, a large amount of pole material is sprayed onto the belt conveyor from the gaps created between the grid bodies in the process of applying the pole material to the grid body by the spraying device, and the raw material is wasted. In addition, since the cost of the pole material is high, the production cost is wasted and environmental pollution is caused. Therefore, improvement in the overall structure design has been demanded.

For this reason, there has been a demand for a gravity cast lattice structure of a storage battery and a transportation method thereof that improve the structure and drawbacks of the prior art.
The object of the present invention is to connect the front end portion and the end portion of each lattice member on the belt conveyor, and the lattice member is hooked with another suspension bar of the lattice member via the hook portion. In the process of transporting and moving each grid on the belt conveyor, there is no gap between the grids, preventing the application of pole materials on the belt conveyor and greatly reducing the cost of raw materials. In addition, it is an object of the present invention to provide a gravitational cast lattice structure of a storage battery and a transportation method thereof that can reduce loss costs in the manufacturing process and prevent environmental pollution.

  In order to solve the above-mentioned problem, according to a first embodiment of the present invention, there is provided a gravitational cast lattice structure of a storage battery including a lattice body, and a peripheral frame is formed on an outer edge of the lattice body, A lattice grid is formed in the peripheral frame, and a suspension bar extending from both sides protrudes from the upper end of the peripheral frame, and the lower end of the peripheral frame is paired with the suspension bar. A hook is projecting on both sides, and a hook is formed at the front end of the hook, and another hanging bar of the lattice is hooked on the hook. A gravity cast grid structure for a storage battery is provided.

  In order to solve the above-described problem, according to the second embodiment of the present invention, a suspension bar is provided at the upper end of the lattice body so as to project from both sides, and the suspension member is disposed at the lower end of the lattice body. A latching rod projecting on both sides so as to make a pair with the bar, a latching portion is formed at the front end of the latching rod, and the hanging bar faces outward between the lattice bodies, The latching rod is directed inward, the latching portion of the latching rod is directed upward, a stepped portion is overlaid on the belt conveyor, the belt conveyor is driven, and the lattice at the bottom end When the body moves outward in conjunction with the driving of the belt conveyor, in the process of moving the bottommost lattice body outward, the latching portion of the latch rod is located above the lattice body. The upper lattice body is pulled outward by being hooked by the suspension bar, and the lattice body has the hook The suspension bar of the other grid body is hooked via a stop, the front end and the end of the grid body are connected on the belt conveyor, and the grid body is moved by an interlocking system. A transport method for a gravity cast grid structure of a storage battery, characterized in that an electrode material is applied, is provided.

  A front end portion and a distal end portion of the lattice body moving on the belt conveyor are connected, and the lattice bodies are dropped and collected from the end of the belt conveyor. It is preferable that the stop portion is automatically detached from the suspension bar of the another lattice body and the hooked state is released.

It is a perspective view which shows the gravity cast lattice structure of the storage battery which concerns on one Embodiment of this invention. It is a perspective view which shows a state when using the gravity cast lattice structure of the storage battery which concerns on one Embodiment of this invention. It is a side view which shows a state when using the gravity cast lattice structure of the storage battery which concerns on one Embodiment of this invention. It is a perspective view which shows a state when using the gravity cast lattice structure of the storage battery which concerns on one Embodiment of this invention. It is a side view which shows a state when using the gravity cast lattice structure of the storage battery which concerns on one Embodiment of this invention. It is a side view which shows the state from which the gravity cast grid structure of the storage battery which concerns on one Embodiment of this invention removed. It is a perspective view which shows the gravity cast grid structure of the conventional storage battery. It is a schematic diagram which shows the manufacturing process of the gravity cast lattice structure of the conventional storage battery.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited thereby.

Please refer to FIG. FIG. 1 is a perspective view showing a gravity cast lattice structure of a storage battery according to an embodiment of the present invention.
As shown in FIG. 1, the gravity cast lattice structure of a storage battery according to an embodiment of the present invention includes a lattice body 1. A peripheral frame 11 is formed on the outer edge of the lattice 1. A lattice grid 12 is formed in the peripheral frame 11, and a suspension bar 13 is provided at the upper end of the peripheral frame 11 so as to project from both sides. At the lower end of the peripheral frame 11, a hooking rod 14 protrudes from both sides so as to make a pair with the hanging bar 13. A hooking portion 141 is formed at the front end of the hooking rod 14.

As will be understood when referring to FIGS. 2 and 3 when the present invention is actually used, when the pole material is applied to each lattice body 1 , the extending direction of the suspension bar 13 of each lattice body 1 is the belt. The both sides of the conveyor in the width direction face, the extending direction of the hooking rod 14 faces the direction opposite to the moving direction of the belt conveyor, the hooking portion 141 of the hooking rod 14 faces upward, and the stepped portion is a belt conveyor. 2 overlaid.
When the belt conveyor 2 is driven, the contact area between the bottommost grid 1 and the belt conveyor 2 is maximized, so the frictional force is maximized, and the bottommost grid 1 is interlocked with the driving of the belt conveyor 2. In the process of moving in the traveling direction , the other upper lattice body 1 is not moved because it is pushed down by gravity, and in the process of moving the bottommost lattice body 1 in the traveling direction , 141 is hooked on the suspension bar 13 of the upper grid body 1 and the upper grid body 1 is pulled in the traveling direction (see FIGS. 4 and 5).
A hanging bar 13 of another grid body 1 is hooked on the grid body 1 via a hooking portion 141 of a hook bar 14, and the front end portion and the end portion of each grid body 1 are on the belt conveyor 2. The pole body 1 is applied to the grid body 1 while the grid body 1 is moved by the interlocking method, and the grid body 1 to which the pole material is applied is transported by the belt conveyor 2 and passes through the drying device to be dried and cured. Then, each lattice 1 is dropped and collected at the end of the belt conveyor 2. When the grid body 1 falls, the latching portion 141 of the latching rod 14 faces upward, so that the latching portion 141 is automatically detached from the suspension bar 13 of the other grid body 1 and is latched. Is released (see FIG. 6).

As can be seen from the above, the gravitational cast lattice structure of the storage battery of the present invention and its transport system are connected to the front end portion and the end portion of each lattice body on the belt conveyor as compared with the conventional structure. A hanging bar of another grid body is hooked on the latching portion of the latch bar, and no gap is generated between the grid bodies when each grid body is transported and moved on the belt conveyor.
For this reason, it can prevent that a pole material is apply | coated on a belt conveyor, the cost concerning a raw material can be reduced significantly, and the loss cost in a manufacture process can be reduced and environmental pollution can be prevented.

  While the preferred embodiments of the present invention have been disclosed above, as may be appreciated by those skilled in the art, they are not intended to limit the invention in any way. Various changes and modifications can be made without departing from the spirit and scope of the present invention. Accordingly, the scope of the claims of the present invention should be construed broadly including such changes and modifications.

DESCRIPTION OF SYMBOLS 1 Lattice body 2 Belt conveyor 3 Grid body 11 Peripheral frame 12 Lattice grid 13 Suspension bar 14 Suspension bar 31 Peripheral frame 32 Grating grid 33 Suspension bar 141 Suspension part

Claims (3)

Gravity cast grid structure of storage battery with grid,
A peripheral frame is formed on the outer edge of the lattice body, a lattice grid is formed in the peripheral frame, and a suspension bar is provided on the upper end of the peripheral frame so as to project from both sides. At the lower end of the frame, hooks are provided on both sides so as to make a pair with the suspension bar, and hooks are formed at the front end of the hooks. , Characterized in that another grid hanging bar is hooked,
Gravity cast lattice structure of storage battery. A transportation method of a gravity cast lattice structure of a storage battery that transports a plurality of lattice bodies,
A plurality of the lattice bodies are partially overlapped on a belt conveyor, and a suspension bar is provided on each upper end of each lattice body so as to project from both sides. hooking rod as hanging form a bar and pairs are projected on both sides, the front end of the locking rod is engaging portion is formed, the hanging direction of extension of the bar of each said grid member There orientation in the width direction on both sides of the belt conveyor, the extending direction of the Kaketome杆faces a direction opposite to the traveling direction of the belt conveyor, the engagement portion of the locking rod is come toward the upper,
Before Symbol belt conveyor is driven, the time of the grid below the partially superimposed plurality of grid on the belt conveyor is moved in conjunction with the driving of the belt conveyor, the grid of the lower The hooks of the hooks are hooked on the suspension bars of the upper grid body, and the upper grid body is pulled in conjunction with the driving of the belt conveyor, and the plurality of grid bodies The electrode material is applied while moving in an array of linear connections ,
Transportation method of gravity cast grid structure of storage battery. The grid from the end of the previous SL belt conveyor are collected and dropped respectively, when the grid is dropping downwards, hanging the prior SL-rated child body the hook portion of the grid to the fall will follow 3. The method of transporting a gravity cast grid structure of a storage battery according to claim 2, wherein the latched state is released automatically from the bar.

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