JP2004275426A - Analysis device housing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To securely prevent an analysis device from falling or the like at drawing a movable body and reduce manufacturing costs as well. <P>SOLUTION: The analysis device housing apparatus D is provided with the movable body P for retaining the analysis device and a housing body L for housing the movable body P retaining the analysis device. The housing body L is provided with a retaining rail 1. The movable body P is provided with a movable rail 2 slidably retained on the retaining rail 1 and telescopically structured into the housing body L. A spring stopper 7 having a retaining hole 4 is provided on the movable rail 2. A lock part 5 for being inserted into the retaining hole 4 through is integrally formed on the retaining rail 1. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a storage device for an analyzer, for example, provided with a shelf for holding the analyzer, a drawer, etc., which can be freely inserted and removed.
[0002]
[Prior art]
[Patent Document 1] Japanese Patent Application Laid-Open No. 2000-236970 A conventional analyzer storage device includes a moving body that holds the analyzer and a storage body that stores the moving body that holds the analyzer. There is a configuration in which a slide rail is provided on the storage body and the movable body so that the movable body can be pulled out from the storage body. The slide rail used in the storage device for the analyzer is disclosed in Patent Document 1. Some have such a configuration.
[0003]
That is, the intermediate rail is held so as to be able to be pulled out with respect to the fixed rail fixed to the gantry, and the movable rail is held so as to be able to be pulled out with respect to this intermediate rail. A spring in which a free end is extended in a direction in which the rail is pulled out and a base end is fixed to the side surface of the moving rail opposite to the side surface on which the locking member of the intermediate rail is provided. A stopper is provided, and the spring stopper is provided with a locking hole for the locking member.
[0004]
Then, in the slide rail, at the time of the pull-out operation in the normal use state, the locking member is fitted into the locking hole of the spring stopper, and the slide rail is brought into a locked state in which the further movement rail cannot be pulled out.
[0005]
[Problems to be solved by the invention]
However, in the slide rail, since the locking member is provided separately from the intermediate rail, the direction of the locking member attached to the intermediate rail may be changed by some impact. In such a case, If the locking member does not get caught in the locking hole and passes through the locking hole, the moving body holding the analyzer is detached from the storage body and falls, which eventually damages the expensive analyzer and damages it. -There was a risk of damage. In addition, the above-mentioned falling down of the analyzer was a problem in terms of safety. In addition, the cost increases because the intermediate rail and the locking member are separately provided.
[0006]
The present invention has been made in consideration of the above-mentioned matters, and an object of the present invention is not only to reliably prevent the analyzer from dropping when the moving body is pulled out, but also to reduce the manufacturing cost. An object of the present invention is to provide a storage device for a device.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, a storage device for an analysis device of the present invention includes a moving body that holds an analysis device, and a storage body that stores a moving body that holds the analysis device. A storage device for an analyzer, wherein a rail is provided, and the movable body is provided with a movable rail slidably held by the holding rail, and the movable body is configured to be able to be pulled out from the storage body, A spring stopper having a locking hole is provided on the moving rail, and a locking portion for inserting the locking hole is integrally formed on the holding rail (claim 1).
[0008]
With the above configuration, it is possible to provide a storage device for an analyzer that can reliably prevent the analyzer from dropping when the moving body is pulled out, and can also reduce the manufacturing cost.
[0009]
That is, in the conventional storage device, since the locking member is provided separately from the intermediate rail (holding rail), the direction of the locking member attached to the intermediate rail (holding rail) may be changed by some impact. In such a case, the locking member may not pass through the locking hole of the moving rail and may pass through the locking hole. Since the locking member is integrally formed with the holding rail, it is possible to reliably prevent the locking member from changing its direction as described above and the locking member from passing through the locking hole, thereby holding the analyzer. Moving the moving body falls off the storage body and falls, causing damage to the expensive analyzer and causing a failure or breakage, which can prevent the damage from becoming enormous. Than it is.
[0010]
Further, since the locking portion is formed integrally with the holding rail, the locking portion can be formed only by performing a sheet metal press working on the holding rail, for example, and the manufacturing cost can be reduced. It becomes possible.
[0011]
Further, the locking portion may have a semi-mountain shape having a slope that becomes lower toward the pulling-out side of the moving rail (claim 2). In this case, when the moving rail is inserted in the holding rail, the moving rail is prevented from being inadvertently disengaged from the holding rail when the moving rail is moved in the pull-out direction. Therefore, a lock portion having an ideal shape that can smoothly move the lock is realized.
[0012]
Furthermore, an end face of the locking portion on the moving direction side of the moving rail may be substantially perpendicular to the holding rail or slightly inclined in a pulling-out direction side thereof. In this case, the locking portion becomes more suitable for manufacturing by sheet metal press working (punching), and by adjusting the inclination angle of the end face of the locking portion on the storage direction side, the locking portion is formed. It is also possible to appropriately adjust the engagement force of the locking hole 4 with the portion 5.
[0013]
Further, an end surface of the moving rail on the storage direction side of the lock portion may be substantially perpendicular to the holding rail or slightly inclined toward the storage direction side. In this case, the engagement between the locking hole and the locking portion is more reliably performed, and the moving body holding the analyzer falls off the storage body and falls, and the expensive analyzer is not used. The effect of preventing damage or the like from occurring due to the damage being added and the damage becoming enormous is increased.
[0014]
Further, the holding rail may be slidably held by a fixed rail fixed to the housing (claim 5). In this case, the moving rail, the moving body having the moving rail, and the analyzer held by the moving body can be pulled out from the housing to the front side.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory view schematically showing a configuration of a storage device D for an analyzer (hereinafter, referred to as a storage device) according to an embodiment of the present invention, and FIG. It is a perspective view shown typically.
The storage device D includes a moving body P that holds an analyzer (not shown), and a storage body L that stores the moving body P holding the analysis device. The fixed rail 3 is provided with a holding rail 1 that is slidably held, and the moving body P is provided with a moving rail 2 that is slidably held by the holding rail 1 to house the moving body P. It is configured to be able to be pulled out from the body L.
[0016]
That is, the storage device D of the present embodiment has a so-called two-stage storage type slide rail composed of the holding rail 1, the moving rail 2 and the fixed rail 3, and the holding rail 1 is mounted on the fixed rail 3. Also, the moving rail 2 is slidably held on the holding rail 1 along the length direction, in other words, slidably held on either side of the moving body P in the pull-out direction A and the storage direction B. Have been. In order to smooth the sliding of the holding rail 1 with respect to the fixed rail 3 and the sliding of the moving rail 2 with respect to the holding rail 1, for example, bearings or the like may be provided at appropriate places.
[0017]
Further, the moving rail 2 is configured to be attachable to and detachable from the holding rail 1 as necessary. This is because the analyzer can be separated (taken out) from the storage body L and can be carried freely.
[0018]
The analyzer is, for example, various gas analyzers and units thereof.
[0019]
The moving body P is, for example, hollow and substantially in the shape of a rectangular parallelepiped, and is made of a member having no top wall, and is configured as a drawer for housing the analyzer therein. The moving rails 2 are provided on outer surfaces of left and right side walls of the moving body P, respectively. In addition, the moving body P is not limited to a structure configured as a drawer as described above, and may have a structure capable of holding the analyzer.
[0020]
The storage body L has, for example, a hollow, substantially rectangular parallelepiped shape, and is made of a member having no front wall surface, and is configured to be able to store one or a plurality of the moving bodies P. In the example, the storage body L is configured as a locker that stores a unit such as a housing of various analyzers (for example, a gas analyzer). The holding rails 1, 1,... Holding the moving rails 2 are arranged inside the storage body L so as to correspond to the moving bodies P to be stored, and furthermore, each holding rail 1 is slidable. Is fixed to an appropriate position inside the storage body L.
[0021]
The holding rail 1, the moving rail 2 and the fixed rail 3 are made of, for example, a metal such as iron or aluminum, or a synthetic resin such as polypropylene, ABS resin, reinforced vinyl resin, polyethylene resin, polyester resin, or polyamide resin. Further, the holding rail 1, the moving rail 2 and the fixed rail 3 are set to have substantially the same length, respectively, and the moving amount of the holding rail 1 and the moving rail 2 is approximately 1% of the total length of the rail to be held. / 2 is set. This is because the dimensions are desirable for stably holding the analyzer. However, it is needless to say that each of the rails 1, 2, 3 is not limited to the above-mentioned dimensions, and may be appropriately set as needed.
[0022]
Then, when the moving body P attached to the moving rail 2 is pulled out, in a normal use state, the analyzer held by the moving body P accidentally slips out of the holding rail 1 together with the moving body P. A lock mechanism is provided between the moving rail 2 and the holding rail 1 in order to prevent falling.
[0023]
The lock mechanism includes a lock portion 5 and a spring stopper 7 provided on side surfaces 1a and 2a of the holding rail 1 and the moving rail 2 that face each other (hereinafter, referred to as opposing side surfaces).
[0024]
Hereinafter, the configurations of the holding rail 1 and the moving rail 2 will be described in detail.
The holding rail 1 has a locking portion 5 through which a locking hole 4 to be described later is inserted at a distal end portion of the facing side surface 1a on the side of the pull-out direction A. The lock portion 5 is formed integrally with the holding rail 1 by a so-called sheet metal press process (punching process). The width of the locking portion 5 in the direction C parallel to the facing side surface 1a and perpendicular to the pull-out direction A (vertical width in FIG. 2) is, for example, about 5 mm.
[0025]
As shown in FIGS. 3A and 3B, the locking portion 5 has a substantially warhead shape when viewed from the front, and the inclination of the moving rail 2 that becomes lower toward the pullout direction A is closer to the pullout direction A. Has a hollow semi-mountain shape on the surface 5a. The surface 5a of the lock portion 5 on the side of the pull-out direction A is a cam surface (inclined surface) that is inclined so as to retreat toward the storage direction B as the distance from the opposing side surface 1a of the holding rail 1 increases. Is formed.
[0026]
Further, the surface 5a and the end surface 5b of the locking portion 5 on the side of the storage direction B are formed so as to have a slope that is higher toward the center in the vertical direction C and lower toward the periphery.
[0027]
Further, an end face 5b of the lock portion 5 on the storage direction B side is formed as an upright side surface which rises substantially perpendicularly to the opposite side surface 1a of the holding rail 1, and the lock portion 5 itself is formed by sheet metal pressing ( An opening 5c is formed in the center portion of the end face 5b because it is formed by punching.
[0028]
A guide ball retainer 9 is provided near the end of the holding rail 1 on the drawing direction A side to smoothly guide the insertion of the moving rail 2 when the moving rail 2 is inserted into the holding rail 1. I have.
[0029]
On the other hand, the movable rail 2 is provided with a spring stopper 7 having a locking hole 4 inserted by the locking portion 5 at a tip end of the facing side surface 2a on the storage direction B side.
[0030]
The spring stopper 7 is a plate spring formed of, for example, a metal or synthetic resin plate-like member, and is configured as a fixed end whose end in the storage direction B is fixed to the facing side surface 2a. In addition, the end on the drawing direction A side is configured as a free end. Further, the spring stopper 7 is protruded from the side surface 2a in an inclined posture so as to be further away from the side surface 2a (moving rail 2) toward the free end side.
[0031]
At the free end of the spring stopper 7, there is provided a guide piece 7a bent toward the facing side surface 2a of the moving rail 2, and the guide piece 7a is closer to the free end side. It is configured to incline so as to approach. And since the said guide piece 7a is inclined as mentioned above, it can get over the said part 5 for a lock.
[0032]
The locking hole 4 is formed, for example, as a square hole, and is provided near the free end of the spring stopper 7 at a position closer to the fixed end than the guide piece 7a.
[0033]
The amount of the spring stopper 7 moving away from the side surface 2a is such that the moving rail 2 is held by the holding rail 1 and at least the edge 4a of the locking hole 4 on the storage direction B side is locked. The size is set to be small enough to be in contact with the end face 5b of the use portion 5.
[0034]
A through hole 8 is provided at a position on the moving rail 2 corresponding to the guide piece 7a of the spring stopper 7. That is, when the spring stopper 7 is deformed in the direction approaching the side surface 2a against its own elastic deformation force by the action of the cam surface 5a of the locking portion 5, the through hole 8 is deformed to a greater degree. This is provided for the purpose of allowing the guide piece 7a to escape. This configuration is desirable in that the guide piece 7a can be formed to a sufficient length, and the guide function can be reliably performed. Further, the distance of the spring stopper 7 from the side surface 2a can be increased, which is desirable in that the function of the spring stopper 7 can be more reliably operated.
[0035]
Next, the operation of the storage device D having the above configuration will be described.
First, a normal use state will be described. In order to pull out the analyzer from the container L, the holder P holding the analyzer is pulled out to the front, so that it can be pulled out together with the moving rail 2 and the holding rail 1. At this time, as shown in FIG. 4A, at the final pull-out position of the holding rail 1 (the limit position of the movement of the holding rail 1 in the pull-out direction A), the end face 5b of the locking portion 5 on the storage direction B side. The spring rail 7 is easily moved over by the guide piece 7a, and the moving rail 2 is further pulled out in the pulling-out direction A. When the locking hole 4 reaches the locking portion 5, the locking portion 5 is engaged with the locking hole 4 by the elastic restoring force of the spring stopper 7, as shown in FIG. An edge 4a of the locking hole 4 on the storage direction B side contacts the end face 5b of the locking portion 5. Therefore, the moving rail 2 is prevented from further moving in the pull-out direction A, and at the same time, the moving rail 2 and the holding rail 1 are integrated via the lock mechanism. In this state, The analyzer is maintained in a posture in which it protrudes from the front surface of the storage body L, and is configured to be used in this posture, for example.
[0036]
In addition, in order to store the analyzer in the storage body L in the normal use state, first, the holder P is pushed in the storage direction B (inside the storage body L). With the pushing operation, as shown in FIG. 4B, the moving rail 2 is pushed in a posture in which the moving rail 2 is integrated with the holding rail 1 via the lock mechanism. Completely pushed into the Subsequently, when the push-in operation is performed, the edge 4b of the locking hole 4 in the pull-out direction A is guided by the cam surface 5a of the locking portion 5, and the entire spring stopper 7 is moved against the elastic restoring force. As shown in FIG. 4 (A), the locking portion 5 finally moves further beyond the free end of the spring stopper 7 as shown in FIG. In this manner, the entire spring stopper 7 is completely pushed into the storage direction B side beyond the locking portion 5, and is finally completely pushed into the holding rail 2.
[0037]
That is, in the storage device D having the above configuration, each time the analyzer is stored, the spring stopper 7 is deformed with the fingertip to release the engagement between the locking portion 5 and the locking hole 4. No troublesome operation is required at all, and the locking action of the lock mechanism can be released by simply pushing the moving rail 2.
[0038]
In a normal use state, when the analyzer is pulled out, the locking hole 4 of the spring stopper 7 is engaged with the locking portion 5, and the edge 4a of the locking hole 4 on the storage direction B side is set. By contacting the end face 5b of the locking portion 5, the moving rail 2 is prevented from further moving in the pull-out direction A, and at the same time, the moving rail 2 and the holding rail 1 are connected via the locking mechanism. As a result, it is possible to prevent the analyzer held by the moving body P from accidentally falling out of the holding rail 1 together with the moving body P and dropping.
[0039]
In the conventional storage device, since the locking member is provided separately from the intermediate rail (holding rail 1), the direction of the locking member attached to the intermediate rail (holding rail 1) may be changed by some impact. In such a case, the locking member 5 may not pass through the locking hole 4 and pass through the locking hole 4 in such a case. Since the locking portion 5 is integrally formed with the holding rail 1, it is possible to reliably prevent the locking member from changing its direction and passing through the locking hole 4 as described above. As a result, the moving body P holding the analyzer may fall off the storage body L and fall, and the expensive analyzer may be damaged, causing a failure or breakage, resulting in enormous damage. It's also possible to prevent such.
[0040]
Next, a description will be given of a work mode in which the analyzer is not completely used and the analyzer is completely separated from the container L and the analyzer is used in a place different from the container L. In order to achieve this working mode, the analyzer is first pulled out of the storage body L by the same operation procedure as that for pulling out the analyzer in the normal use state. By this pulling-out operation, the moving rail 2 and the holding rail 1 are changed from the state shown in FIG. 4A to the state shown in FIG. Subsequently, as shown in FIG. 4 (C), the spring stopper 7 is deformed by the fingertip or the like against the side surface 2a of the moving rail 2 against its elastic restoring force, so that the locking portion 5 and the locking hole 4 are formed. 4D, the moving rail 2 is further pulled out in the pull-out direction A, and the moving rail 1 is finally pulled out from the holding rail 2 as shown in FIG. By such an operation, the analyzer is completely separated from the storage body L and becomes in a portable state.
[0041]
Further, in order to store the analyzer completely separated from the storage body L in the storage body L again, it is only necessary to push the moving rail 2 into the holding rail 1 from the front end thereof. That is, when the moving rail 2 is pushed from the tip of the holding rail 1, as shown in FIG. 4 (D), the spring stopper 7 acts against its own elastic restoring force by the action of the cam surface 5a, thereby sequentially moving the moving rail. 2 so as to approach the facing side 2a. Then, as shown in FIG. 4 (B), the locking hole 4 is engaged with the locking portion 5 and the spring stopper 7 is temporarily moved away from the side surface 2a of the moving rail 2 temporarily. Reference numeral 2 denotes an operation posture integrated with the holding rail 1 in a normal use state. Thereafter, in the same manner as the procedure and process for storing the analyzer in the normal use state described above, by further pushing the moving rail 2, the edge 4 b of the locking hole 4 in the pull-out direction A side becomes the locking portion. 5 is guided by the cam surface 5a, and the entire spring stopper 7 is deformed so as to approach the opposing side surface 2a of the moving rail 2 against its elastic restoring force, and as shown in FIG. 5 finally goes further beyond the free end of the spring stopper 7. In this manner, the entire spring stopper 7 is completely pushed into the storage direction B side beyond the locking portion 5, and is finally completely pushed into the holding rail 2.
[0042]
Therefore, the work of separating the analyzer from the storage body L and using the analyzer again in the storage body L can be easily performed, and the storage apparatus D has excellent usability.
[0043]
Further, in the analysis device D, since the locking portion 5 is integrally formed with the holding rail 1, the locking portion 5 can be formed only by performing sheet metal pressing on the holding rail 1. It is also possible to reduce the manufacturing cost.
[0044]
In the above embodiment, the end surface 5b of the lock portion 5 is formed as an upright side surface that rises substantially perpendicularly to the opposite side surface 1a of the holding rail 1 (that is, as shown in FIG. 3, Although the angle α between the facing side surface 1a and the end surface 5b of the holding rail 1 is formed to be approximately 90 °), the present invention is not limited to such a configuration. For example, the end surface 5b may be replaced with the holding rail 1 so as to be slightly inclined in the pull-out direction A side from the standing state, that is, the angle α between the end face 5b and the opposing side face 1a of the holding rail 1 is slightly larger than 90 °. It may be formed. In other words, the angle α may be freely set, for example, between 90 and 120 °. In this case, the locking portion 5 becomes more suitable for manufacturing by the sheet metal pressing (punching), and the locking hole for the locking portion 5 is adjusted by adjusting the inclination angle α of the end face 5b. It is also possible to appropriately adjust the engaging force of No. 4.
[0045]
Conversely, the end surface 5b is slightly inclined in the storage direction B side from the state in which the end surface 5b rises substantially perpendicular to the holding rail 1, that is, the end surface 5b and the opposing side surface 1a of the holding rail 1 The angle α may be slightly smaller than 90 °. In other words, the angle α may be freely set, for example, between 90 and 60 °. In this case, the engagement between the locking hole 4 and the locking portion 5 is more reliably performed, and the moving body P holding the analyzer is detached from the storage body L and falls off, which is expensive. The effect of preventing the analysis apparatus from being damaged and causing a failure or breakage, resulting in serious damage, etc., is increased. Further, by adjusting the inclination angle α of the end face 5b, the engagement force of the locking hole 4 with respect to the locking portion 5 can be appropriately adjusted.
[0046]
Further, the locking portion 5 shown in FIGS. 3 (A) and 3 (B) is formed by expanding a part of the holding rail 1 and further breaking the part. However, the locking portion 5 may be formed only by partially expanding the holding rail 1 by pressing or the like without breaking the holding rail 1 at all.
[0047]
Further, in the above embodiment, the storage body L is provided with the fixed rail 3 and the holding rail 1 slidably held by the fixed rail 3, and the storage device D is provided with a slide rail of a so-called two-stage storage type. However, the present invention is not limited to such a configuration. For example, the holding rail 1 may be directly fixed to the housing L without providing the fixed rail 3. In this case, the number of components is reduced, and the storage device D can be manufactured at lower cost.
[0048]
【The invention's effect】
As described above, according to the present invention, it is possible to provide the storage device D for an analyzer that can reliably prevent the analyzer from dropping when the moving body P is pulled out.
[0049]
That is, in the storage device D having the above-described configuration, the load is applied to the moving body P, and the members constituting the storage device D are out of dimension, so that the locking hole 4 of the spring stopper 7 is Even when the locking portion 5 is deviated from the center, the locking portion 5 does not pass through the locking hole 4 and the locking claw portion 6 provided on the locking portion 5 and / or The locking groove 10 can prevent the above-mentioned passage, so that the risk of the expensive analyzer falling from the container P can be eliminated, and the damage due to the failure or breakage of the analyzer can be surely eliminated. In addition, safety is improved by preventing the analyzer from falling.
[0050]
Further, due to the locking claw portions 6 and / or the locking groove portions 10 provided on the locking portion 5, a load is applied to the moving body P, and the members constituting the storage device D are out of dimension. Thus, it is possible to allow the locking hole 4 and the locking portion 5 of the spring stopper 7 to be displaced from the center to some extent. Therefore, the moving rail 2 and the holding rail constituting the storage device D are provided. Even if the strength and precision during manufacture are reduced to some extent, its functionality and usability will not be impaired, and further cost reduction can be achieved.
[Brief description of the drawings]
FIG. 1 is an explanatory view schematically showing a configuration of a storage device for an analyzer according to one embodiment of the present invention.
FIG. 2 is a perspective view schematically showing a configuration of a main part of the embodiment.
FIGS. 3A and 3B are a perspective view and a longitudinal sectional view schematically showing a configuration of a lock portion in the embodiment.
FIGS. 4A to 4D are explanatory views schematically showing the operation of the main part of the embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Holding rail, 2 ... Moving rail, 4 ... Locking hole, 5 ... Locking part, 7 ... Spring stopper, D ... Storage device for analyzers, L ... Storage body, P ... Moving body.

Claims (5)

A moving body that holds the analyzer and a housing that houses the moving body that holds the analyzer are provided, and a holding rail is provided in the housing, and the moving body is slidably moved by the holding rail. What is claimed is: 1. A storage device for an analyzer, wherein a movable rail to be held is provided, and said movable body is configured to be able to be pulled out from said storage body. A locking part for inserting the locking hole is formed integrally with the analyzer. The storage device for an analyzer according to claim 1, wherein the lock portion has a semi-mountain shape having an inclination that becomes lower toward the pull-out direction side of the moving rail. 3. The storage device for an analyzer according to claim 1, wherein an end face of the lock portion on the side of the storage direction of the moving rail is substantially perpendicular to the holding rail or slightly inclined in a direction of pulling out from the holding rail. . 3. The storage device for an analyzer according to claim 1, wherein an end face of the lock portion on the storage direction side of the moving rail is substantially perpendicular to the holding rail or slightly inclined to the storage direction side. . The storage device for an analyzer according to any one of claims 1 to 4, wherein the holding rail is slidably held by a fixed rail fixed to the storage body.

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