JP3211367U - Multi-part transport and storage container for assembled electrochemical cells - Google Patents

Abstract

A multi-part transport and storage container for an assembled button battery is provided. A multi-part transport and storage container (200) for an assembled electrochemical cell (100) comprising a tray (201) and a cover (202) for the tray (201), the tray (201) comprising a recess (206), The cover 202 is provided with a recess 207, and the tray 201 and the cover 202 of the cell 100 in which the recess 207 of the cover 202 and the recess 206 of the tray 201 are transported and stored when the cover 202 is placed on the tray 201. Designed to form a receptacle for the cover 202, the cover 202 is formed of an elastic material, and the recess 207 of the cover 202 is inserted into the recess 207 only when the cell 100 is accompanied by the elastic expansion of the recess 207. Are dimensioned to be able to [Selection] Figure 2

Description

  The invention described below relates to a multi-part transport and storage container for assembled electrochemical cells, particularly assembled button batteries.

  Within the scope of the present application, the term “preassembled cells” is a cell, on the outside of which are spaced apart electrical conductors, whereby the cell is integrated into an electrical circuit. It should be understood as meaning what can be done.

  For example, a typical cylindrical type cell such as a button cell is very compact and can therefore be easily stored and transported, but the assembled cell is very vulnerable. In general, the electrical conductors fixed to the outside of them protrude from the outside and are easily bent or broken. Therefore, assembled cells must be handled with special care during transport and storage.

  The purpose of the invention described below is to make available a container for an assembled electrochemical cell that can ensure reliable storage and reliable transport of the cell.

  This object is achieved by a transport and storage container having the features of claim 1. Preferred embodiments of the transport and storage container are described in the dependent claims 2-5. The terms of all claims are hereby referred to the contents of this specification.

  The transport and storage container according to the present invention has a multi-part design. That is, it includes at least a tray and a cover for the tray.

  As mentioned at the outset, the container serves for the transport and storage of assembled electrochemical cells, preferably cylindrical type assembled electrochemical cells, in particular assembled button cells.

  Both the tray and the cover are provided with a recess. Particularly preferably, the tray and the cover are each provided with the same number of recesses.

  The tray and cover are designed to combine and form a recess in the cover and a receptacle for the cell in which the tray recess is transported and stored when the cover is placed on the tray.

  The tray and cover preferably each have two opposing flat sides (which are preferably in the form of receptacles) and a peripheral edge. Particularly preferably, the tray recess and the cover recess are each arranged on one of the flat sides. Once the covers are correctly placed on the tray so that the flat sides with the recesses lie on top of each other, the recesses join together in each case in pairs to form one of the receptacles To do. Therefore, the number of receptacles usually corresponds to the number of recesses in the tray and also corresponds to the number of recesses in the cover.

  According to the present invention, the cover is formed from an elastic material. At the same time, the recess in the cover is dimensioned so that it can only be inserted into the recess when the cell is accompanied by an elastic expansion of the recess. As a result of the elastic expansion and the inevitably associated tendency towards elastic recovery of the elastic material, the cover exerts pressure on the cells inserted into the recess, which gives a suitably selected dimension of the recess And securely fix the cell in the receiver.

The cell in which the container is designed for containment preferably has at least one of the following characteristics:
-The cell has a cylindrical design,
The cell comprises a casing comprising a casing shell and two flat end faces;
– One of the casing shell and one of the end faces has different polarities.

  A typical representative example of these cells is a button battery as described above. As is generally known, a button cell is a cylindrical type electrochemical cell whose overall height is smaller than its overall diameter.

  In general, a button cell includes a casing made up of two cup-shaped casing halves. The casing halves each comprise a base and a circumferential side wall. One of the casing halves is preferably inserted into the other such that the side walls of the casing halves overlap to form a double-walled annular portion. The outer side wall then forms the casing shell and the base of the casing half forms the end face. Usually, the inserted casing half has a negative polarity and the other casing half has a positive polarity.

The cell in which the container is designed for containment preferably further has at least one of the following characteristics, preferably all combinations of the following characteristics:
The first electrical conductor protruding from the outside of the casing is fixed to the casing shell; Particularly preferably, the first electrical conductor is axially aligned with respect to the cylindrical geometry of the cell. However, in some embodiments, the first electrical conductor can also be aligned parallel to the flat end face relative to the cell geometry.
The second electrical conductor protruding from the outside of the casing is fixed to a surface of a different polarity from the casing shell; The second electrical conductor is preferably aligned parallel to the flat end face with respect to the cylindrical geometry of the cell.
-Particularly preferably, the first and second electrical conductors are aligned inclined relative to each other. That is, in particular, the first electrical conductor is axially aligned with the cylindrical geometry of the cell, and the second electrical conductor is aligned parallel to the flat end face with respect to the cylindrical geometry of the cell. Is the time. However, in certain embodiments, the first and second electrical conductors are also particularly when both the first and second electrical conductors are aligned parallel to the flat end face relative to the cylindrical geometry of the cell. Can be aligned parallel to each other.

  The first and second electrical conductors are preferably hard metal plates, metal wires or metal pins, and where appropriate are single or multi-core electrical conductors covered with an insulating material. In general, the first and second electrical conductors are straight lines. That is, it has no bend.

  Certain preferred geometric features of the tray have already been given: two opposing flat sides (preferably in the form of a rectangle) as well as a perimeter. Particularly preferably, the tray has an overall rectangular design.

  Particularly preferably, the tray comprises a frame, which is provided for receiving a cover and surrounds a flat surface on which the recess is located. The flat surface is preferably the aforementioned flat side surface and takes the form of a rectangle having a recess.

Particularly preferably, the tray comprises at least one of the following features:
The tray is produced from a synthetic material, for example from polyvinyl chloride, polyethylene or polystyrene, in particular by thermoforming or injection moulding,
-The tray is made of inelastic material,
The tray is made of an antistatic material or the tray is coated with an antistatic material,
-The tray is designed to be stackable.

  Particularly preferably, the recess of the tray includes a recess for receiving the electrical conductor of the assembled cell.

  Certain preferred geometric features of the cover (two opposing flat sides (preferably taking the form of a rectangle) as well as the perimeter) are also already given. Particularly preferably, the cover has an overall rectangular design.

  The size of the cover is preferably adapted to the aforementioned frame of the tray so that the cover can be fitted into the frame.

Particularly preferably, the cover comprises at least one of the following features:
The cover consists of a foam material (open or closed cell), in particular foamed polypropylene (EPP), foamed polyethylene (EPE), foamed polystyrene (EPS) or foamed polyurethane (PU);
-The cover recess has a penetrable design.

  The cover preferably includes a separate groove through the cover to make the test contact. Particularly preferably, the recess of the cover includes this groove. This groove is provided to allow electrical testing of the assembled cell stored in the receptacle without having to remove the cell from the container.

  The container according to the present invention preferably comprises 40-100 receptacles for the cell. Particularly preferably, the receptacle is placed with a cell.

  The transport and storage container according to the present invention provides a special advantage when removing the cell from the container. This is because for this purpose the container is rotated and the cover can be placed down. At that time, the tray can be easily removed. This means allows free access to the assembled cells inserted in the recesses of the cover, which partly protrude from the cover, for example half of their size (diameter or height), for example The resulting access is possible for removal or for further work steps such as testing.

  The described and further features of the container according to the invention will be apparent from the following description of the preferred embodiment represented in the drawings. In embodiments, the individual features of the present invention may be realized by themselves or in combination with each other. The described embodiments are only useful for explanation and for a better understanding of the invention and should not be understood as limiting in any way.

FIG. 1 shows an assembled button cell. FIG. 2 shows a preferred embodiment of a transport and storage container according to the invention and two enlarged parts of said container. FIG. 3 shows seven stacks of the transport and storage containers of FIG. FIG. 4 shows the container of FIG. 2 in a removed state.

  FIG. 1 shows an assembled button cell 100. The button cell 100 includes a casing shell 101 and a flat surface 102. The surface 102 has a negative polarity. The casing shell 101 has a positive polarity. The first electric conductor 103 is fixed to the casing shell 101 by welding. This first electrical conductor 103 is axially aligned with the cylindrical geometry of the button cell 100. The second electrical conductor 104 is fixed to the surface 102 by welding. The second electrical conductor 104 is aligned parallel to the flat surface 102. The first electrical conductor 103 and the second electrical conductor 104 are disposed at right angles to each other.

  FIG. 2 shows a perspective view of a preferred embodiment of a transport and storage container 200 according to the present invention and two detail enlargements (rotated view) of said container. The container includes a tray 201, a cover 202, and an intermediate layer 203. The intermediate layer 203 is needed for cases where additional trays are to be stacked on the tray 201.

  The tray 201 is a rectangular shaped product made of a thermoformed synthetic material. The tray includes a frame 204, which is provided to accommodate the cover 202 and surrounds a flat surface 205 in which a recess 206 is disposed. Overall, 10 recesses are arranged on the flat surface 205 with 5 recesses, i.e. 50 recesses in each case in 5 rows and 10 recesses. In the figure, assembled button cells, such as the button cell 100 depicted in FIG. 1, are placed in all of the recesses away from each other.

  The tray recess 206 includes two elongated indentations 206a and 206b to accommodate the assembled battery electrical conductors 103 and 104, respectively. The recess 206a serves to accommodate the electrical conductor 104. The indent includes a right angle, which corresponds to the relative orientation of the electrical conductors 103 and 104 to each other. An assembled battery, such as the button battery depicted in FIG. 1, can be placed in the recess 206 so as not to move with respect to rotation. This holds even stronger. This is because they are further fixed by the cover 202 in a position that does not move with respect to rotation.

  The cover 202 is a rectangular shaped product made of a foam material. The size of the cover 202 fits the frame 204 of the tray 201 so that the cover can fit into the frame 204.

  The cover 202 is made of an elastic foam material. It includes 10 penetrable recesses 207 5 times, ie 50 recesses in 5 rows of 10 recesses in each example. Once the cover 202 is mated to the frame 204, the tray recess 206 and the cover recess 207 are attached in pairs in each example to form a receptacle for the assembled button cell. In this connection, the recess 207 of the cover 202 is dimensioned so that it can only be inserted into the recess 207 when the button cell is accompanied by an elastic expansion of the recess. As a result of the tendency of elastic expansion, and necessarily the elastic recovery of the associated elastic material, the cover 202 exerts pressure on the battery inserted into the recess, which securely secures the battery in the recess 207. .

  The thickness of the cover 202 roughly corresponds to half the diameter of the button battery. Generally, the recess 206 provides 40% to 60% space of the button cell volume. Correspondingly, generally 60% to 40% of the button cell volume is located in the recess 207 when the cover 202 is fitted into the frame 204.

  The cover 202 serves not only to secure the battery against movement against rotation but also to protect its electrical conductors.

  The recesses 207 in the cover 202 each include a separate groove 207a through the cover for performing a test contact. This groove makes it possible to carry out an electrical test of the assembled battery stored in the receptacle without having to remove the battery from the container. For this purpose, the groove 207a is open at the intersection 208 of the elongated depressions 206a and 206b, respectively. Thus, the test contact pushed through the groove 207a can now contact the electrical conductors 103 and 104 simultaneously.

  The intermediate layer 203 is a molded product formed into a rectangle made of paperboard or cardboard. Where appropriate, the molding may be printed or labeled.

  FIG. 3 shows seven stacks 300 of transport and storage containers as represented in FIG. In principle, the stack may consist of any number of transport and storage containers.

  FIG. 4 shows the container 200 represented in FIG. 2 in a removed state. For this purpose, the container 200 is rotated and placed with the cover 202 down and preferably on the intermediate layer 203. When the tray 201 is then lifted up, free access to the assembled battery is possible. The assembled battery can be easily removed individually. Thus, the cover 202 serves as a “donor” for the assembled battery.

Claims (5)

A multi-part transport and storage container (200) for an assembled electrochemical cell (100) comprising a tray (201) and a cover (202) for the tray (201),
The tray (201) is provided with a recess (206), the cover (202) is provided with a recess (207), and the tray (201) and the cover (202) are placed on the tray (201). The recess (207) of the cover (202) and the recess (206) of the tray (201) are designed to form a receptacle for the cell (100) to be transported and stored when removed
The cover (202) is formed from an elastic material and the recess (207) of the cover (202) is inserted into the recess (207) only when the cell (100) is accompanied by the elastic expansion of the recess (207). Multi-component transport and storage container characterized in that it is dimensioned so that it can be A multi-part transport and storage container according to claim 1, characterized in that it is designed to accommodate a cell (100) having at least one of the following characteristics:
-The cell (100) has a cylindrical design;
The cell comprises a casing comprising a casing shell (101) and two flat end faces (102);
-One of the casing shell (101) and the end face (102) has a different polarity from each other;
A first electrical conductor (103) protruding from the outside of the casing is fixed to the casing shell (101);
A second electrical conductor (104) protruding from the outside of the casing is fixed to an end face (102) of a different polarity from the casing shell (101),
The first and second electrical conductors (103; 104) are hard metal plates or metal wires,
The first electrical conductor (103) is axially aligned with respect to the cylindrical geometry of the cell (100);
The second electrical conductor (104) is radially aligned with the cylindrical geometry of the cell (100);
The first and second electrical conductors (103; 104) are tilted and aligned with respect to each other; A multi-part transport and storage container according to claim 1 or 2, characterized in that the tray (201) comprises at least one of the following features:
The tray (201) is manufactured from a synthetic material, in particular by thermoforming or injection molding,
The tray (201) is made of an inelastic material,
The tray (201) is made of an antistatic material or the tray (201) is coated with an antistatic material,
The recess (206) of the tray (201) includes a recess (206a; 206b) for receiving an electrical conductor (103; 104);
-The tray (201) has a rectangular design,
The tray (201) comprises a frame (204), which is provided for receiving the cover (202) and surrounds a flat surface (205) on which the recess (206) is located To
The tray (201) is designed to be stackable. A multi-part transport and storage container according to any of claims 1 to 3, characterized in that the cover (202) comprises at least one of the following features:
The cover (202) consists of a foam material, in particular foamed polypropylene (EPP), foamed polyethylene (EPE), foamed polystyrene (EPS) or foamed polyurethane (PU) foam;
The recess (207) of the cover (202) has a penetrable design;
The recess (207) of the cover (202) includes a separate groove (207a) through the cover (202) for performing the test contact;
The cover (202) has a rectangular design; The multi-part transport and storage container according to any one of claims 1 to 4, having the following characteristics:
The container comprises 40-100 receptacles for the cell (100);
-The cell (100) is placed in the receptacle.

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