JP2007103421A - Assembly structure of module case - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an assembly structure of a module case with high versatility. <P>SOLUTION: In the assembly structure of the module case, the module case 1 is provided with a first main side board part 21, a second main side board part 22, a first end part side board part 23, a second end part side board part 24, a base board part 25 and a panel 26. In a position where a size L of a depth direction is divided into sizes LA and LB, halved objects 1a and 1b at a mode where the module case 1 is cut into a direction orthogonal to a direction where a rail member 30 extends are combined so as to constitute the assembly structure. One of halved objects 1a and 1b is applied to a module case different in a depth size. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an assembly structure of a module case, and more particularly to an assembly structure of a module case that accommodates an electronic device.

  Conventionally, a module case that houses various controllers, converters, and other electronic devices and is attached to a DIN (Deutsches Institut fur Normung) rail member (hereinafter simply referred to as “rail member”) based on the standards of the German Standards Association, for example. in use. As shown in FIG. 39, since a plurality of such module cases 101 are arranged in parallel on the rail member 130, a substantially rectangular parallelepiped shape is mainly adopted as an external shape.

  For this reason, the module case 101 is orthogonal to the direction in which the rail member 130 extends, and the first main side plate portion 121 and the second main side plate portion 122 that face each other with an interval in the direction in which the rail member 130 extends. A first end side plate portion 123 and a second end side plate portion 124 facing each other with a gap in the direction, a bottom plate portion 125 positioned at the lower end, and a panel 126 positioned at the upper end.

As a document disclosing such a method for fixing the module case 101 to the rail member 130, there is, for example, Patent Document 1. In Patent Document 1, a claw portion for locking the rail member 130 and a lever for operating the same on either one of the first end portion side plate portion 123 and the second end portion side plate portion 124 (not shown). And the claw part is opened by pressing the lever, and the attaching / detaching operation is performed while the module case 101 is tilted with respect to the rail member 130. The conventional module case is configured as described above.
Japanese Utility Model Publication No. 5-46079

  However, the conventional module case has the following problems. The module case 101 is assembled by assembling predetermined members to be the first main side plate 121, the second main side plate 122, the first end side plate 123, the second end side plate 124, the bottom plate 125, and the panel 126. The substantially rectangular parallelepiped shape (see FIG. 39).

  There are several methods for assembling the module case. For example, as shown in FIG. 40, the first main side plate 121, the second main side plate 122, the first end so as to cover the bottom plate 125 on which the printed circuit board 127 such as a controller is disposed. There is an assembly structure in which a member obtained by integrally molding the side plate portion 123, the second end side plate portion 124, and the panel 126 is attached.

  As shown in FIG. 41, a printed circuit board 127 is accommodated in a member formed by integrally molding the first main side plate portion 121, the first end side plate portion 123, and the second end side plate portion 124. There is an assembly structure for attaching the bottom plate portion 125, the second main side plate portion 122 and the panel 126.

  Further, as shown in FIG. 42, the printed circuit board 127 is accommodated with respect to a member obtained by integrally molding the first main side plate 121, the first end side plate 123, the second end side plate 124 and the bottom plate 125. In addition, there is an assembly structure for attaching the second main side plate portion 122 and the panel 126 thereto.

Alternatively, as shown in FIG. 43, a printed circuit board is formed on a member obtained by integrally molding the first main side plate 121, the first end side plate 123, the second end side plate 124, the bottom plate 125, and the panel 126. 127 has an assembly structure in which the second main side plate portion 122 is accommodated.

  The module case 101 is prepared in a plurality of sizes depending on the size of the electronic device to be accommodated. For this reason, in the assembly structure of the conventional module case, it is necessary to prepare a member that becomes the first main side plate portion, the first end side plate portion, or the like for each size, which is one of the factors that hinder the reduction of the production cost. It was.

  Also, for example, when replacing an electronic device or the like housed in an existing module case with a larger size electronic device, the module case must be replaced with a module case of a size corresponding to the size. There was a problem that the existing module case could not be utilized.

  The present invention has been made to solve the above problems, and an object thereof is to provide an assembly structure of a module case having high versatility.

  The assembly structure of the module case according to the present invention is detachably attached to a rail member extending in one direction, and has predetermined dimensions in a width direction perpendicular to the one direction, a height direction, and a depth direction along the one direction. Each of a plurality of module cases having different dimensions in the depth direction in a direction perpendicular to one direction at a position that bisects the dimension in the depth direction. The module case is configured by combining two divided bodies in a cut form. Of the plurality of module cases, in the first module case having the first dimension in the depth direction, the first module case is cut in a direction orthogonal to one direction as a divided body at a position where the first dimension is divided into two equal parts. A first divided body and a second divided body each having a first divided dimension that is half of the first dimension are combined. In the second module case having the second dimension longer than the first dimension in the depth direction, as the divided body, the second divided body and the second divided dimension obtained by subtracting the first divided dimension from the second dimension. A three-part body is combined.

  According to the assembly structure of the module case, one of the first divided body and the second divided body constituting the first module case has a second module case having a depth dimension different from that of the first module case. Applies to assembly of Accordingly, it is not necessary to create a module case for each size, and a single divided body can be applied to a plurality of module cases having different sizes, thereby obtaining a highly versatile module case assembly structure using the divided body. be able to.

  For a third module case having a third dimension longer than the second dimension in the depth direction among the plurality of module cases, a third divided body constituting the second module case as a divided body, A fourth divided body having a third divided dimension obtained by subtracting the second divided dimension from the three dimensions may be combined.

  Further, in each of the plurality of module cases, a fitting portion extending along the depth direction is formed on the upper end portion of one of the two divided bodies and the upper end portion of the other divided body, respectively. It is preferable that a predetermined member is fitted to the fitting portion of one divided body and the fitting portion of the other divided body.

  Specifically, a plate-like panel that closes the upper end of the module case is provided as the predetermined member, and the panel is divided into a groove portion of the first fitting portion of one divided body and a second fitting portion of the other divided body. It is preferable to fit in the groove portion.

  Thereby, a panel can be handled as a single-piece | unit and the versatility of the components which comprise a module case can be improved.

  In addition, the predetermined member includes an extension member for extending the height direction of the module case, and the extension member includes one split extension corresponding to one of the two split bodies and the other split. A third fitting portion extending along the depth direction is formed at the lower end portion of the one split extension body, and the upper end portion of the one split extension body is formed at the upper end portion of the one split extension body. Is formed with a fourth fitting portion extending along the depth direction, and a lower fitting portion of the other divided extension body is formed with a fifth fitting portion extending along the depth direction. A sixth fitting portion extending along the depth direction is formed at the upper end portion of the extension body, and the third fitting portion of one split extension body is fitted to the first fitting portion of one split body. And the fifth fitting portion of the other divided extension body is fitted to the second fitting portion of the other divided body. Masui.

  Thereby, it can change easily according to the magnitude | size of the electronic device which accommodates the dimension of the height direction of a module case, without preparing a new module case.

  In this case as well, as a predetermined member, a plate-like panel that closes the upper end of the module case is further provided, and the panel is provided with a groove portion of the fourth fitting portion of one split extension body and the other split extension body. You may make it fit in the groove part of a 6th fitting part.

  Further, in each of the plurality of module cases, the rail member is sandwiched from one side and the other side in the width direction at the end side portions facing each other with a gap in the width direction orthogonal to the depth direction. Preferably, a pair of sandwiching members are provided, and each of the plurality of module cases is fixed to the rail member by sandwiching the rail member by the pair of sandwiching members.

  Accordingly, by grasping the pair of sandwiching portions so as to sandwich the module case, the module case can be attached and detached from the vertical direction without being inclined with respect to the rail member.

  In each of the plurality of module cases, a pair of protrusions extending in the height direction is formed on the outer surface of one of the two divided bodies, and the outer side of the other divided body. A pair of fitting grooves extending in the height direction are formed on the surface, and each of the plurality of module cases is formed with a pair of protrusions formed in one module case in the other module case. In the plurality of module cases fixed to the rail member in a state of being fitted in the pair of fitting grooves, by operating the pair of sandwiching members, Preferably, any one module case can be removed from and attached to the rail member.

  Further, in each of the plurality of module cases, each of the one divided body and the other divided body exchanges signals between an electronic device accommodated in one module case and an electronic device accommodated in another module case. It is preferable that the connector part of one module case and the connector part formed in the other module are in contact with each other in a state in which a connector part for performing the above is provided and the plurality of module cases are fixed to the rail member.

  Thereby, electrical conduction between the module cases can be achieved without using an additional cable.

In addition, the connector portion provided in the module case located at the extreme end in a state in which the plurality of module cases are fixed to the rail member, with a protection member that covers and protects the connector portion provided in the module case. Is preferably covered with a protective member.

  Thereby, the connector part of the module case located in the end can be protected among several module cases connected mutually.

  A module case and its assembly structure according to an embodiment of the present invention will be described. As shown in FIG. 1, the module case 1 is detachably attached to a rail member 30 and has a width W and a height H in a direction orthogonal to a direction in which the rail member 30 extends. There is a depth L in the extending direction, and various electronic devices (not shown) such as various controllers and converters are accommodated in the module case 1.

  The module case 1 includes a first main side plate portion 21 and a second main side plate portion 22, a first end portion side plate portion 23 and a second end portion side plate portion 24, a bottom plate portion 25 and a panel 26. In the module case 1, the module case 1 is cut in a direction perpendicular to the direction in which the rail member 30 extends, particularly at a position where the dimension L in the depth direction is divided into the dimensions LA and LB. It is configured by combining the divided body 1a and the divided body 1b. As will be described later, one of the two divided bodies 1a and 1b is also applied to module cases having different depth dimensions. The first end side plate portion 23 and the second end side plate portion 24 are provided with a pair of sandwiching members 15 for fixing the module case 1 to the rail member.

(Depth of module case)
The aspect of the combination of the divided bodies in the module case 1 will be described in more detail. The module case 1 is generally prepared with module cases having different dimensions depending on the size of the electronic device accommodated in the module case 1. As such a module case, for example, as shown in FIG. 2, three module cases 1 having different dimensions L1 to L3 (L1 = 22.5 mm, L2 = 35 mm, L3 = 45 mm) in the depth direction will be exemplified.

  First, in the module case 1 having the shortest depth dimension L1 (left end toward the paper surface), the module case 1 is formed as a divided body in a direction orthogonal to the direction in which the rail member extends at a position that divides the depth dimension L1 into two equal parts. The first divided body 2 and the second divided body 3 each having a first divided dimension (D1 = D2 = 11.25 mm) which is a half of the depth dimension L1 are combined.

  Further, in the module case 1 having a depth dimension L2 longer than the depth dimension L1 (the center of the drawing), the second divided body 3 is divided as the divided body, and the first divided dimension (D1 = D2) is subtracted from the depth dimension L2. The third divided body 4 having two divided dimensions (D3 = 23.75 mm) is combined.

  Then, in the module case 1 having the depth dimension L3 longer than the depth dimension L2 (the right end toward the paper surface), the third divided body 4 is divided as the divided body, and the second divided dimension (D3) is subtracted from the depth dimension L3. A fourth divided body 5 having a third divided dimension (D4 = 21.25 mm) is combined.

Next, the structure of each divided body 2-5 is demonstrated. As shown in FIG. 3, a pair of protrusions 50 extending in the height direction are formed on the outer surface of the first divided body 2. In this case, the protruding portion 50 includes a corner portion extending from a portion corresponding to the first main side plate portion 21 to a portion serving as the first end portion side plate portion, and a portion corresponding to the first main side plate portion 21 to the second end portion. It is formed in the corner | angular part over the part used as a side plate part, respectively. Further, an opening 52 for exposing the connector portion is formed in a portion corresponding to the first main side plate portion 21 in the first divided body 2.

  On the other hand, as shown in FIG. 4, the first divided body 2 extends in the depth direction at the upper end portions of the portion serving as the first end portion side plate portion and the portion serving as the second end portion side plate portion. The fitting parts 51 to be formed are respectively formed.

  Next, as shown in FIG. 5, a pair of fitting grooves 53 extending in the height direction are formed on the outer surface of the second divided body 3. In this case, the fitting groove 53 includes a corner portion extending from a portion corresponding to the second main side plate portion 22 to a portion serving as the first end portion side plate portion, and a portion corresponding to the second main side plate portion 22 to the second end portion. It is formed in the corner | angular part over the part used as a side plate part, respectively. Further, an opening 52 for exposing the connector portion is formed in a portion corresponding to the second main side plate portion 22 in the second divided body 3.

  On the other hand, as shown in FIG. 6, the second divided body 3 extends in the depth direction at the upper end portions of the portion serving as the first end portion side plate portion and the portion serving as the second end portion side plate portion. The fitting parts 51 to be formed are respectively formed. The fitting portion 51 of the first divided body 2 and the fitting portion 51 of the second divided body 3 are formed at the same height.

  Next, as shown in FIG. 7, a pair of protrusions 50 extending in the height direction are formed on the outer surface of the third divided body 4. In this case, the protruding portion 50 includes a corner portion extending from a portion corresponding to the first main side plate portion 21 to a portion serving as the first end portion side plate portion, and a portion corresponding to the first main side plate portion 21 to the second end portion. It is formed in the corner | angular part over the part used as a side plate part, respectively. Further, an opening 52 for exposing the connector portion is formed in a portion corresponding to the first main side plate portion 21 in the third divided body 4.

  On the other hand, as shown in FIG. 8, the third divided body 4 extends in the depth direction at the upper end portions of the portion serving as the first end portion side plate portion and the portion serving as the second end portion side plate portion. The fitting parts 51 to be formed are respectively formed.

  Next, as shown in FIG. 9, a pair of fitting grooves 53 extending in the height direction are formed on the outer surface of the fourth divided body 5. In this case, the fitting groove 53 includes a corner portion extending from a portion corresponding to the second main side plate portion 22 to a portion serving as the first end portion side plate portion, and a portion corresponding to the second main side plate portion 22 to the second end portion. It is formed in the corner | angular part over the part used as a side plate part, respectively. Further, an opening 52 for exposing the connector portion is formed in a portion corresponding to the second main side plate portion 22 in the fourth divided body 5.

  On the other hand, as shown in FIG. 10, the fourth divided body 5 extends in the depth direction at the upper end portions of the portion serving as the first end portion side plate portion and the portion serving as the second end portion side plate portion. The fitting parts 51 to be formed are respectively formed. The fitting portion 51 of the third divided body 4 and the fitting portion 51 of the fourth divided body 5 are formed at the same height.

  Moreover, as shown in FIG. 11, the panel 6 for closing the upper opening end of each module case when combining the corresponding divided bodies has end portions 6a that fit into the groove portions of the fitting portions 51 of the divided bodies. And the opening part 6b which exposes the socket etc. of an electronic device is formed.

Next, the assembly procedure of the module case by the 1st division body 2-the 4th division body 5 mentioned above is demonstrated. For example, as shown in FIG. 12, the inner part of the first divided body 2 and the inner part of the second divided body 3 are opposed to each other, and the first divided body 2 approaches the second divided body 3 as shown by the arrows. By inserting the end portion 6a of the panel 6 into the groove portion of the fitting portion 51 of the first divided body 2 and the groove portion of the fitting portion 51 of the second divided body 3 as shown in FIG. A module case 1 having a dimension L1 is assembled. The 1st division body 2 and the 2nd division body 3 are fixed with a screw (not shown) etc., for example.

  Similarly, the module case 1 having the depth dimension L2 is obtained by fitting the end 6a of the panel 6 into the groove portion of each fitting portion 51 with the second divided body 3 and the third divided body 4 facing each other. Are assembled. Then, the module case 1 having the depth dimension L3 is assembled by fitting the end portion 6a of the panel 6 into the groove portion of each fitting portion 51 with the third divided body 4 and the fourth divided body 5 facing each other. It is done. In this way, the module cases 1 having different depth dimensions are assembled.

(Height dimension of module case)
Next, the division | segmentation extension body for making the height of the module case 1 higher corresponding to each of the 1st division body 2-the 4th division body 5 is demonstrated. First, as shown in FIG. 14, in the divided extended body 11 corresponding to the first divided body 2 or the third divided body 4, the first divided body extends in the depth direction at the lower end portion inside the divided extended body 11. A fitting portion 60 that fits into the fitting portion 51 formed in the body 2 or the third divided body 4 is formed. In addition, a fitting portion 61 extending along the depth direction similar to the fitting portion 51 is formed at the upper end portion of the divided extension body 11.

  On the other hand, as shown in FIG. 15, in the divided extension body 12 corresponding to the second divided body 3 or the fourth divided body 5, the second divided body 3 or A fitting portion 60 that fits into the fitting portion 51 formed in the fourth divided body 5 is formed. A fitting portion 61 extending along the depth direction similar to the fitting portion 51 is formed at the upper end portion of the split extension body 12.

  Next, a procedure for assembling the module case including the above-described split extended bodies 11 and 12 will be described.

  First, as shown in FIG. 16, with respect to the fitting portion 51 formed on the inner side of the first divided body 2 or the third divided body 4, the fitting portion 60 formed on the lower end portion of the divided extension body 11 is provided. By fitting, as shown in FIG. 17, the divided extension body 11 is attached to the first divided body 2 or the third divided body 4.

  On the other hand, as shown in FIG. 18, with respect to the fitting portion 51 formed on the inner side of the second divided body 3 or the fourth divided body 5, the fitting portion 60 formed on the lower end portion of the divided extension body 12 is provided. By fitting, as shown in FIG. 19, the split extension body 12 is attached to the second split body 3 or the fourth split body 5.

  Next, as shown in FIG. 20, the inner part of the first divided body 2 or the like to which the divided extension body 11 is attached and the inner part of the second divided body 3 or the like to which the divided extension body 12 is attached are opposed to each other. As indicated by the arrows, the panel is placed on the groove portion of the fitting portion 61 of the divided extension body 11 and the groove portion of the fitting portion 61 of the divided extension body 12 while bringing the second divided body 3 and the like closer to the first divided body 2 and the like. By fitting the end portion 6a of 6, the module case 1 extended in the height direction is assembled as shown in FIG.

  In the module case 1 described above, the case where one split extension body is provided has been described as an example. However, by further attaching the same split extension bodies 11 and 12, as shown in FIG. The module case 1 having a high height can be easily assembled.

(Attachment mode to rail member)
In this module case 1, as shown in FIG. 23, the first end side plate portion 23 and the second end side plate portion 24 are used to sandwich the rail member from one side and the other side in the width direction W. A pair of sandwiching members 15 is provided. The sandwiching portion 15 is configured to pull the claw portion 16 away from each other against the urging force of the spring 18 and the claw portion 16 that grips the rail member, the spring 18 that urges the claw portion 16 toward the inside. The lever 17 is provided. The lever 17 is pivotally supported by a pair of bearing portions 19a and 19b provided on the first end side plate portion 23 and the second end side plate portion 24, respectively.

  As shown in FIG. 24, the claw portions 16 are separated from each other against the urging force of the spring 18 by sandwiching the upper portion of the lever 17 as indicated by the arrow. In this state, the module case is placed on the rail member 30. 25, when the lever 17 is released, the claw portion 16 sandwiches the rail member 30 by the biasing force of the spring 18, and the module case 1 is fixed to the rail member 30.

  3 to 22, in particular, the sandwiching portion 15 is not shown, but for example, as shown in FIG. 1, a pair of bearings is provided in one of the two divided bodies constituting the module case. One bearing portion 19a of the portions 19a and 19b is formed, and the other bearing portion 19b is formed in the other divided body. Thus, when the module case is assembled with the two divided bodies facing each other, one end side of the shaft portion of the lever 17 is attached to the bearing portion 19a of one divided body, and the other end side is a bearing of the other divided body. It can be easily attached to the portion 19b.

  In this module case 1, the module case 1 is moved relative to the rail member 30 by operating the levers 17 of the pair of sandwiching members 15 formed on the first end side plate portion and the second end side plate portion facing each other. It is possible to attach and remove the rail member 30 from the vertical direction without tilting.

  Therefore, the manner in which the module case 1 is attached to the rail member 30 will be specifically described based on the fact that the attachment and removal can be performed in the vertical direction as described above and the relationship between the protrusion and the fitting groove.

  As described above, a pair of protrusions 50 extending in the height direction is formed on the outer surface of one of the two divided bodies 2, 4 of the two divided bodies constituting the module case 1, and the other A pair of fitting grooves 53 extending in the height direction are formed on the outer surfaces of the divided bodies 3 and 5 (see FIGS. 3 to 10).

  The protrusion 50 and the fitting groove 53 are for connecting one module case and another module case. For example, as shown in FIG. 26, by fitting a pair of protrusions 50 provided in one module case 1 into a pair of fitting grooves 53 provided in another module case 1, As shown in FIG. 27, a plurality of module cases 1 are sequentially connected. In this way, as shown in FIG. 28, the plurality of module cases 1 connected to each other are fixed to the rail member 30.

  In this state, when replacing one module case 1 (for example, a module case located in the center), the pair of claws 16 are held by holding the pair of levers 17 so as to sandwich the one module case 1. By opening, the module case 1 is released from the state of being fixed to the rail member 30. Next, when the module case 1 is lifted while the lever 17 is gripped, as shown in FIG. 29, the protrusion 50 is guided by the fitting groove 53 and the module case 1 is pulled out upward. .

When a new module case is installed in the space (gap) of the module case that has been pulled out in this way, the protrusion of the new module case (not shown) is fitted to the adjacent one of the module cases. The new module case is inserted into the rail member 30 by inserting into the groove and inserting the protrusion of the other module case adjacent to the fitting groove and pushing it downward to perform the reverse operation to the above-described operation. Can be fixed.

  In addition, although the case where the module cases having the same depth dimension are attached to the rail member has been illustrated and described as the mounting manner of the module case described above, the ridge portion is fitted into the fitting groove between the adjacent module cases. Thus, as shown in FIG. 30, module cases 1 having different depth dimensions can be mixed and attached to the rail member 30.

  Even when module cases 1 having different depth dimensions are attached to each other, as shown in FIG. 31, by operating the lever 17 of one of the module cases 1 to the rail member 30. Can be attached or removed.

  As described above, the adjacent module cases are fixed to the rail member with the protrusions fitted in the fitting grooves, and therefore, the first main side plate portion of one module case and the second of the other module case. The main side plate part contacts each other. By utilizing this, electrical connection (conduction) between the module cases can be performed. Then, next, the aspect of the electrical continuity between module cases is demonstrated.

(Mode of electrical continuity between module cases)
As shown in FIG. 32, each module case 1 attached to the rail member 30 has openings 52 formed in the first main side plate portion and the second main side plate portion, respectively. As shown in FIGS. 33 and 34, connector portions 40a and 40b for electrical conduction are exposed in the opening 52. One connector portion 40a is formed so as to protrude outward, and the other connector portion 40b is formed in a planar shape.

  As shown in FIG. 35, in a state where a plurality of module cases 1 are connected to each other and attached to the rail member 30, one module case is between one module case 1 and another module case 1 adjacent to each other. The connector part 40a exposed in one opening part comes into contact with the connector part 40b exposed in the opening part of another module 1.

  As a result, power can be supplied to the electronic device housed in the module case 1 or signals can be exchanged between the electronic devices without using an additional cable such as a jumper. FIG. 35 shows a state where a gap is provided between the module case 1 and the module case 1 in order to show the contact state between the connector part 40a and the connector part 40b.

  Further, in the module case located at each end of the plurality of module cases connected to each other, as shown in FIG. 35, the connector portions 40a and 40b are exposed, and thus a protective portion 45 is mounted to cover the connector portions 40a and 40b. . As shown in FIG. 36, the protector 45 is provided with a terminal portion 47 that contacts the connector portions 40a and 40b. In FIG. 36, a protruding terminal portion 47 that contacts the flat connector portion 40b is shown. In the protector 45 for the protruding connector portion 40a, a flat terminal portion 47 is formed (see FIG. 38).

In addition, a pair of fitting grooves 46 are formed in the protector 45, and as shown in FIG. 37, the protector 45 is fitted to the module case 1 by fitting the fitting groove 46 into the protruding portion of the module case. Will be attached. On the other hand, in the protector for the protruding connector portion 40a, a ridge portion that fits into a pair of fitting grooves of the module case is formed. Thus,
As shown in FIG. 38, the protector 45 which covers a connector part with respect to the module case 1 located in each end is each mounted | worn.

  In the assembly structure of the module case described above, the module case is formed by combining two divided bodies in a mode in which the module case is cut in a direction orthogonal to the direction in which the rail member extends at a position where the dimension in the depth direction is divided into two. A module case configured and longer than the depth dimension is combined by applying one of the two divided bodies.

  That is, one of the two divided bodies constituting the module case having a certain depth dimension can be applied to a module case having a depth dimension longer than the depth dimension. Further, the height of the module case can be easily changed by the split extension body. As a result, there is no need to create a module case for each size, and one divided body can be applied to a plurality of module cases of different sizes. An assembly structure can be obtained.

  In the module case 1, a pair of sandwiching members 15 are formed on the first end side plate portion and the second end side plate portion facing each other, and the pair of levers 17 of the sandwiching portion 15 is connected to the module case. The module case 1 can be attached and removed from the vertical direction without being inclined with respect to the rail member 30.

  In addition, a pair of protrusions 50 provided in one module case 1 is combined with the fact that protrusions and fitting grooves extending in the height direction are formed in each module case. A plurality of module cases 1 can be sequentially connected by being fitted into a pair of fitting grooves 53 provided in the module case 1, and a specific module is selected from the plurality of connected module cases. Only the case can be removed.

  Furthermore, in a plurality of module cases fixed to the rail member in a state of being connected to each other, connector portions formed so as to be exposed at respective portions of the first main side plate portion and the second main side plate portion of the adjacent module cases By bringing them into contact with each other, electrical conduction between the module cases can be achieved without using an additional cable.

  And the module which equipped with the protector provided with the protrusion which fits into the protrusion groove of a module case, or the protrusion groove of a module case, and this is located in an end, respectively By attaching to the case 1, the connector part can be covered and protected.

  Note that the dimensions (L1, L2, L3) given in the assembly structure of the module case described above are merely examples, and various sizes corresponding to the size of the electronic device can be adopted as the size of the module case. it can.

  The embodiments disclosed herein are merely examples in all respects, and the present invention is not limited thereto. The present invention is defined by the terms of the claims, rather than the scope described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is a perspective view which shows the structure of the module case which concerns on embodiment of this invention. In the same embodiment, it is a perspective view which shows the module case from which each depth dimension differs. In the embodiment, it is a first perspective view showing a first divided body of two divided bodies constituting one module case. FIG. 4 is a second perspective view showing the first divided body shown in FIG. 3 in the same embodiment. In the embodiment, it is a first perspective view showing a second divided body of two divided bodies constituting one module case. FIG. 6 is a second perspective view showing the second divided body shown in FIG. 5 in the same embodiment. In the embodiment, it is a first perspective view showing a third divided body of two divided bodies constituting another module case. FIG. 8 is a second perspective view showing the third divided body shown in FIG. 7 in the same embodiment. In the embodiment, it is a first perspective view showing a fourth divided body of two divided bodies constituting still another module case. FIG. 10 is a second perspective view showing the fourth divided body shown in FIG. 9 in the same embodiment. In the same embodiment, it is a perspective view which shows the panel which covers the upper end of a module case. In the same embodiment, it is a disassembled perspective view which shows 1 process of the assembly procedure of a module case. FIG. 4 is a partially broken perspective view showing the assembled module case in the same embodiment. In the embodiment, it is a perspective view which shows one division | segmentation extension body. In the same embodiment, it is a perspective view which shows another division | segmentation extension body. In the embodiment, it is a perspective view which shows one process of the attachment procedure to the division body of one division | segmentation extension body. In the same embodiment, it is a perspective view which shows the state which attached the one division | segmentation extension body to the division body. In the embodiment, it is a perspective view which shows one process of the attachment procedure to the division body of another division | segmentation extension body. In the embodiment, it is a perspective view which shows the state which attached the other division | segmentation extension body to the division body. In the embodiment, it is an exploded perspective view showing one step of the assembly procedure of the module case by the divided body to which the divided extended body is attached. FIG. 4 is a partially broken perspective view showing the assembled module case in the same embodiment. In the same embodiment, it is a partially broken perspective view showing a module case assembled with a further divided extension. In the same embodiment, it is a side view which shows a module case. In the embodiment, it is a partially broken side view showing one step of a procedure for attaching the module case to the rail member by the sandwiching member. In the same embodiment, it is a partially broken side view showing a state in which the module case is fixed to the rail member by the sandwiching member. In the same embodiment, it is one perspective view for explaining an attachment procedure for attaching to a rail member while connecting a plurality of module cases by a ridge and a fitting groove. In the same embodiment, it is a top view which shows the state where several module cases were connected by the protrusion part and the fitting groove. In the embodiment, it is a perspective view showing a state in which a plurality of module cases are connected by a protrusion and a fitting groove. In the same embodiment, it is a perspective view which shows a mode that one module case is removed from a state with which several module cases were connected, or a mode that it attaches. In the same embodiment, it is a perspective view which shows the state with which the several module case from which the dimension of a depth direction differs was connected. In the same embodiment, it is a perspective view which shows a mode that the one module case is removed or attached from the state with which the several module case from which the dimension of a depth direction differs was connected. In the embodiment, it is one perspective view which shows the module case for demonstrating the electrical continuity between module cases. In the same embodiment, it is a partial side view showing the connector portion exposed to the opening of the module case. In the embodiment, it is a fragmentary sectional view which shows the connector part exposed to the opening part of a module case. In the same embodiment, it is a side view which shows a mode that the connector parts contact in the state in which the some module case was connected. In the embodiment, it is a perspective view which shows the protection part which covers and protects a connector part. In the same embodiment, it is a perspective view which shows the state which attached the connector part to the module case. In the embodiment, it is a partial side view showing a state in which a protection unit is mounted on a module case positioned at an end with respect to a plurality of module cases coupled to each other. It is a perspective view which shows the conventional module case attached to the rail member. It is a perspective view which shows the 1st example of the assembly structure in the conventional module case. It is a perspective view which shows the 2nd example of the assembly structure in the conventional module case. It is a perspective view which shows the 3rd example of the assembly structure in the conventional module case. It is a perspective view which shows the 4th example of the assembly structure in the conventional module case.

Explanation of symbols

1a, 1b divided body, 2 1st divided body, 3nd divided body, 4 3rd divided body, 5 4th divided body, 6 panel, 6a end, 6b opening, 11, 12 divided extended body, 15 sandwiched Member, 16 claw part, 17 lever, 18 spring, 19a, 19b bearing part, 21
1st main side plate part, 22 2nd main side plate part, 23 1st end part side plate part, 24 2nd end side plate part, 25 Bottom plate part, 26 Panel, 40a, 40b Connector part, 45 Protection part, 46 Fitting groove 47 terminal part, 50 protrusion part, 51, 60, 61 fitting part, 52 opening part, 53 fitting groove.

Claims (10)

A module that is detachably attached to a rail member that extends in one direction, and that has a predetermined dimension in each of a width direction, a height direction, and a depth direction along the one direction, and accommodates an electronic device. The assembly structure of the case,
Each of the plurality of module cases having different dimensions in the depth direction is combined with two divided bodies in a mode in which the module case is cut in a direction orthogonal to the one direction at a position where the dimension in the depth direction is divided into two. Configured by
Among the plurality of module cases, in the first module case having a first dimension in the depth direction, the first divided body is divided into the first dimension in a direction orthogonal to the one direction at a position that bisects the first dimension. A first divided body and a second divided body each having a first divided dimension which is half of the first dimension of the aspect in which the module case is cut are combined,
In the second module case having a second dimension that is longer than the first dimension in the depth direction, the second divided body is obtained by subtracting the first divided dimension from the second dimension as the divided body. An assembly structure of a module case, which is combined with a third divided body having dimensions.   Among the plurality of module cases, in a third module case having a third dimension longer than the second dimension in the depth direction, the third divided body and the second dimension from the third dimension are used as the divided body. The assembly structure of the module case of Claim 1 combined with the 4th division body which has the 3rd division dimension which deducted the division dimension. In each of the plurality of module cases, a first fitting portion extending along the depth direction is formed at an upper end portion of one of the two divided bodies,
A second fitting portion extending along the depth direction is formed at the upper end of the other divided body of the two divided bodies,
The assembly structure of the module case according to claim 1 or 2, wherein a predetermined member is fitted to the first fitting portion of the one divided body and the second fitting portion of the other divided body. As the predetermined member, comprising a plate-like panel that closes the upper end of the module case,
The module case assembly structure according to claim 3, wherein the panel is fitted into a groove portion of the first fitting portion of the one divided body and a groove portion of the second fitting portion of the other divided body. As the predetermined member, an extension member for extending the height direction of the module case,
The extension member is
One split extension corresponding to the one split body of the two split bodies;
The other divided extension corresponding to the other divided body,
A third fitting portion extending along the depth direction is formed at the lower end portion of the one split extension body,
A fourth fitting portion extending along the depth direction is formed at the upper end portion of the one split extension body,
A fifth fitting portion extending along the depth direction is formed at the lower end portion of the other split extension body,
A sixth fitting portion extending along the depth direction is formed at the upper end portion of the other split extension body,
The third fitting portion of the one divided extension body is fitted to the first fitting portion of the one divided body, and the other divided extension is fitted to the second fitting portion of the other divided body. The assembly structure of the module case of Claim 3 which fitted the said 5th fitting part of the body. As the predetermined member, further comprising a plate-like panel that closes the upper end of the module case,
6. The assembly of a module case according to claim 5, wherein the panel is fitted into a groove portion of the fourth fitting portion of the one split extension body and a groove portion of the sixth fitting portion of the other split extension body. Construction. In each of the plurality of module cases, the rail member is sandwiched between one side and the other side in the width direction at end side portions facing each other with a gap in the width direction orthogonal to the depth direction. A pair of pinching members for,
The module case assembly structure according to claim 1, wherein each of the plurality of module cases is fixed to the rail member by sandwiching the rail member by the pair of sandwiching members. In each of the plurality of module cases, a pair of protrusions extending in the height direction is formed on the outer surface of the one divided body of the two divided bodies, and the other divided body is formed. A pair of mating grooves extending in the height direction are formed on the outer surface of
Each of the plurality of module cases is formed on the rail member in a state where the pair of protrusions formed in one module case is fitted in the pair of fitting grooves formed in the other module case. Fixed,
In the plurality of module cases fixed to the rail member, it is possible to remove any of the plurality of module cases from the rail member by operating the pair of sandwiching members. An assembly structure of a module case according to claim 7. In each of the plurality of module cases, each of the one divided body and the other divided body receives signals from an electronic device housed in one module case and an electronic device housed in another module case. A connector part is provided for communication,
The said connector part of one module case and the said connector part formed in the other module contact in the state in which the said several module case was being fixed to the said rail member. The assembly structure of the module case. A protective member for covering and protecting the connector portion provided in the module case;
The assembly structure of the module case according to claim 9, wherein the connector portion provided on the module case located at the end is covered with the protection member in a state where the plurality of module cases are fixed to the rail member. .

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