JP2011117776A - Rack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rack for dealing with a calibration package in the same way as a normal sample. <P>SOLUTION: The calibration package 100 includes: a body 102 in which a plurality of cells 108 are juxtaposed and coupled, and accommodate a pseudo sample as a calibration fluid; and a sidewall 104 downwardly extended from one side end of the body 102 in the cell disposition direction. The surface of the sidewall 104 is marked with a package bar code 110 indicating identification information on the calibration package 10. The package rack 10 includes: an accommodation recess 18 for standing and holding a plurality of the cells 108 in a state that the sidewall 104 is outwardly placed; and a mirror 24 installed opposite to the sidewall 104 at an acute angle with the sidewall 104 from a top view. The mirror 24 inflects an optical path of image light of the package bar code in a horizontal plane. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a rack that holds a calibration package containing a plurality of calibration fluids.

  Currently, measuring devices for measuring characteristic values of liquid samples, such as enzyme immunoreaction measuring devices, are widely known. In such a measuring apparatus, calibration processing is appropriately performed in order to maintain the accuracy of the measurement value. In this calibration process, a pseudo sample (calibration fluid) that is a fluid having a known characteristic value is used. That is, in the calibration process, a plurality of types of pseudo samples are measured by the measurement device, and the output value of the measurement device is calibrated based on a comparison between the obtained measurement value and a known specific value.

  Some calibration packages that house and package a plurality of pseudo samples used for such calibration processing have been proposed. Such a calibration package includes a main body portion in which a plurality of cells containing a calibration fluid (pseudo sample) are arranged and connected, and a side wall extending at least downward from one end of the main body portion in the cell arrangement direction. Is provided. In many cases, an image indicating identification information of the calibration package, for example, a barcode or the like is attached to the side wall of the calibration package.

  Here, in order to perform such a calibration process smoothly, it is desirable that this pseudo sample is accommodated in a rack and transported in the same manner as a normal sample. In order to facilitate management, it is also desired to effectively use an identification image such as a barcode attached to each calibration package.

JP-A-6-207934 Japanese National Patent Publication No. 10-503366 JP 2007-24537 A JP 2005-338938 A

  However, as described above, the calibration package containing the pseudo sample or the like has a special shape having a side wall extending at least downward from one end of the main body in addition to the main body. For this reason, it has been difficult for the conventional rack to accurately hold the fluid package upright. In addition, an ordinary image has an identification image (barcode or the like) attached to the side surface of a specimen container (such as a test tube) that accommodates each sample, whereas the calibration package has an identification image attached to the side wall. Yes. In other words, when set in the measurement apparatus, the position where the identification image can be seen differs between the specimen container containing a normal sample and the calibration package containing a pseudo sample. Therefore, in order to read the identification image attached to the calibration package, another reading device is required in addition to the reading device that reads the identification image of the sample container. This has the problem of increasing costs.

  Patent Documents 1 and 2 disclose techniques for holding a plurality of cuvettes and wells. However, since the cuvette or well to be held here does not have a side wall, it cannot be applied to holding the calibration package described above. Patent Documents 3 and 4 disclose techniques for reading a bar code using a reflector such as a mirror, but these techniques are not intended for a calibration package. In other words, conventionally, there has been no rack that can hold a calibration package with a special shape in a state in which an identification image can be read, in other words, a rack that can be handled in the same manner as a normal sample.

  Accordingly, an object of the present invention is to provide a rack that can handle a calibration package in the same manner as a normal sample.

  The package rack of the present invention is a package rack that holds a calibration package in which a plurality of calibration fluids are individually accommodated, and the calibration package includes a plurality of cells each containing a calibration fluid. And a side wall extending at least downward from one side end of the main body in the cell arrangement direction, and a package side identification image indicating identification information of the calibration package is added to the surface thereof. When the package rack is provided with a side wall, the package rack has an accommodation recess that holds the plurality of cells upright with the side wall positioned outside, and an angle that forms an acute angle with the side wall when viewed from above. And a reflective material that is disposed to face the side wall and bends the optical path of the image light of the package side identification image in a horizontal plane.

  In a preferred aspect, a lid is further provided that can be switched between an open state that allows detachment of the cell from the housing recess and a closed state that inhibits detachment of the cell from the housing recess. In another preferred aspect, the lid includes an opening that exposes a part of the upper surface of each cell to the outside in the closed state.

  According to the package rack of the present invention, it is possible to bend the direction of the image light of the package side identification image in a direction that can be read by the reading device provided in the measuring device while standing and holding a plurality of cells. As a result, in the measuring apparatus, the calibration package can be handled in the same manner as a normal sample.

It is the perspective view and front view of a calibration package. It is a perspective view of the package rack of this embodiment. It is a front view of the package rack of this embodiment. It is a perspective view of a package rack in a state where a calibration package is set. It is a perspective view of a package rack in a state where a calibration package is set. It is a schematic top view around a package rack. It is a schematic perspective view of a normal sample container and a sample rack. It is an image figure which shows the mode of the handling of the sample rack in a measuring apparatus.

  Hereinafter, a package rack according to an embodiment of the present invention will be described with reference to the drawings. First, with reference to FIG. 1, a calibration package 100 to be held by the package rack of the present embodiment will be described. FIG. 1 is a perspective view and a front view of the calibration package 100.

  The calibration package 100 accommodates and packages a calibration fluid used for calibration processing of a measurement device (for example, an immune reaction measurement device or the like) that measures a characteristic value of a liquid sample, so-called a pseudo sample. There are various types of the calibration package 100. Here, the calibration package 100 used for the calibration process of the immune reaction measuring apparatus will be described as an example.

  The calibration package 100 of the present embodiment accommodates six types of pseudo samples and is packaged. A pseudo sample is a fluid whose characteristic value is known. When the measuring device is calibrated, the pseudo sample is measured by the measuring device to be calibrated, and the measured value obtained at that time is compared with a known characteristic value. Then, the output value of the measuring device is calibrated as appropriate based on the comparison result. Here, since it is difficult to calibrate properly with only one pseudo sample, normally, a plurality of pseudo samples having different characteristic values are used for the calibration process. A package for the plurality of pseudo samples is a calibration package 100.

  The calibration package 100 of this embodiment includes a main body 102, a side wall 104 connected to one end of the main body 102, a front wall 106 and a back wall connected to the front and back surfaces of the main body 102 (not visible in the drawing). ) Etc. The main body 102 is a part in which six cells 108 containing pseudo samples are arranged in a line and connected. Each cell 108 is a substantially frustoconical cylindrical body having a smaller diameter as it approaches the bottom side, and a pseudo sample having a known characteristic value is accommodated therein. The upper end opening of the cell 108 is completely covered with a film material having a light shielding property, and contamination and deterioration of the pseudo sample are prevented. Here, in the calibration process, it is necessary to suck the pseudo sample with the suction nozzle provided in the measuring apparatus. At the time of this suction, the suction nozzle breaks through the film material covering the upper end opening of the cell 108 and enters the cell 108 to suck the pseudo sample accommodated in the cell 108.

  A substantially flat thin plate functioning as a front wall 106 and a back wall is connected to the front surface and the back surface of the main body 102. Both the front wall 106 and the back wall extend from the vicinity of the upper end of the main body 102 to the intermediate height position of the main body 102. Further, on the outer surface of the front wall 106, information on the calibration package 100, for example, character information 112 indicating the product name of the calibration package, the type of the pseudo sample contained in each cell, the expiration date, etc. It is attached. The user appropriately determines the type or the like of the calibration package 100 by looking at the character information 112 written on the front wall 106.

  A side wall 104 is connected to one end of the main body 102 in the cell arrangement direction. The side wall 104 is a thin plate material in which only the vicinity of the upper end is connected to one side end of the main body 102. The side wall 104 has a rectangular shape that is slightly wider than the main body 102 and slightly higher than the main body 102. In other words, the lower end of the side wall 104 is lower than the lower end of the cell 108. For this reason, when the calibration package 100 is placed on a horizontal base, the calibration package 100 is self-supporting in an unstable state in which the upper surface is inclined as shown in FIG. Further, as is apparent from FIG. 1B, the side wall 104 is connected to the main body 102 in a slightly inclined state so as to move away from the main body 102 as approaching the lower end.

  On the outer surface of the side wall 104, a package-side barcode 110 that is an identification image indicating identification information of the calibration package 100 is attached. This package-side barcode 110 has the same format as an identification barcode attached to a sample container that contains a normal sample. Here, a one-dimensional barcode is illustrated, but if it is the same format as the identification image attached to the sample container, other types of identification images, for example, a two-dimensional barcode, a character string, etc. There may be.

  Next, the package rack 10 of this embodiment that holds the calibration package 100 upright will be described with reference to FIGS. 2 and 3 are a perspective view and a front view of the package rack 10 of the present embodiment. 4 and 5 are a perspective view and a front view of the package rack 10 in a state where the calibration package 100 is set.

  The package rack 10 of the present embodiment holds the calibration package 100 upright and is made of resin or the like. The package rack 10 has substantially the same size as a sample rack for storing a normal sample, and is roughly divided into a rack body 12 and a lid body 14 that is rotatable with respect to the rack body 12.

  A T-shaped groove 16 is formed on the bottom surface of the rack body 12 in the same manner as a normal sample rack. The T-shaped groove 16 is a groove that engages with a rail of a rack transport mechanism provided in the measuring apparatus. By providing the T-shaped groove 16, the package rack 10 can be transported by a rack transport mechanism provided in the measuring apparatus, as in a normal sample rack.

  On the upper surface of the rack body 12, a plurality of cells 108 are inserted, and an accommodation recess 18 for standing and holding the plurality of cells 108 is formed. As is apparent from FIG. 2, the housing recess 18 has a shape in which a round hole into which one cell can be inserted is connected to both ends of a long hole into which four cells arranged in a row can be inserted.

  The width of the housing recess 18 is smaller than the interval between the front wall 106 and the back wall of the calibration package 100. Therefore, when a plurality of cells 108 are inserted into the receiving recess 18, the plurality of cells 108 enter the receiving recess 18, but the lower ends of the front wall 106 and the back wall of the calibration package 100 are at the rack body 12. It will contact | abut to the upper surface of this, and will be in the state exposed outside. From another point of view, the lower side of the front wall 106 and the back wall of each cell 108 is inserted into the receiving recess 18, but the upper side of the front wall 106 and the lower side of the back wall is above the rack body 12. It will protrude from the top surface of.

  The upper corner of the rack body 12 is cut into a substantially rectangular shape. This notch is provided to expose the side wall 104 of the calibration package 100 to the outside without interfering with the rack body 12 when the plurality of cells 108 are inserted into the accommodating recess 18. From another point of view, the rack body 12 is shaped such that a plurality of cells 108 can be accommodated in the accommodating recess 18 with the side wall 104 positioned outward.

  Here, a stepped surface 20 is formed at one end of the rack body 12 at a position lower than the formation surface of the housing recess 18 (the upper surface of the rack body) by cutting out the upper corner of the rack body 12 into a substantially rectangular shape. Will be. A reflective portion 22 is formed so as to protrude from the step surface 20.

  The reflecting portion 22 is a plate-like rib that is erected from the stepped surface 20 and has a mirror 24 as a reflecting material attached to the surface thereof. In other words, it can be said that the reflection portion 22 is a rib having a reflection surface that reflects light on the surface thereof. In the top view, the reflection part 22 has the side wall 104 of the calibration package 100 and the reflection surface (the surface of the mirror 24) facing each other, and the angle formed by both is an acute angle, specifically, about 45 degrees. It is installed with a proper posture. Note that “about 45 degrees” is merely an example, and if the image light of the package-side barcode attached to the side wall 104 is reflected by the mirror 24, the optical path of the image light can be bent to the front side, Other angles may be used.

  The reflection portion 22 has a size such that the upper end thereof is substantially the same height as the upper end of the calibration package 100 set in the rack body 12. The mirror 24 affixed to the reflecting portion can reflect the entire image of the package-side barcode 110 attached to the side wall 104 of the calibration package 100. By providing the mirror 24, the calibration package 100 can be easily handled even by a conventional measuring apparatus, which will be described in detail later.

  A rack-side barcode 28 indicating the identification information of the package rack 10 is attached to the side end surface of the rack body 12 opposite to the reflecting portion 22. The rack-side barcode 28 has the same format as an identification barcode attached to a sample rack that contains a normal sample container. Here, a one-dimensional barcode is illustrated, but if it is the same format as the identification image attached to the sample rack, other types of identification images, for example, a two-dimensional barcode, a character string, etc. There may be.

  The lid 14 is a member provided to prevent unintentional detachment of the calibration package 100 set on the rack body 12. The lid 14 is in a closed state that inhibits the detachment of the calibration package 100, and the detachment of the calibration package 100. It is possible to take an open state that allows

  The lid body 14 is a substantially U-shaped member having a cross section including a front plate 30 and a rear plate 32 facing each other, and a top plate 34 connecting the front plate 30 and the rear plate 32. The lid body 14 is rotatable about a rotation shaft 40 provided at an end portion of the rack body 12 opposite to the reflection portion 22. Further, an engaging claw 38 is formed at the end of the front plate 30 and the rear plate 32 of the lid body 14 on the side opposite to the rotating shaft 40. In the closed state, the engagement claw is inserted into and engaged with a locking hole 26 formed on the upper surface of the rack body 12 to maintain the closed state.

  Each of the front plate 30 and the rear plate 32 is formed with a confirmation window 36 that is a substantially rectangular opening. The confirmation window 36 is provided at a position corresponding to the character information 112 attached to the front wall 106 of the calibration package 100, and the character information 112 can be visually confirmed even in the closed state. ing. By providing such a confirmation window 36, it is possible to more reliably prevent an incorrect type of the calibration package 100.

  The top plate 34 of the lid 14 is a part that prevents the calibration package 100 from coming off by covering a part of the calibration package 100 set on the rack body 12 from the upper side in the closed state. The top plate 34 is formed with a passage opening 42 that is a substantially rectangular opening. In the closed state, the passage opening 42 is positioned and sized so that a part of the upper surface of each cell 108 provided in the calibration package 100 can be exposed to the outside. By providing the passage opening 42, the suction nozzle provided in the inspection apparatus can enter the cell 108 even in the closed state. Further, when the suction nozzle moves into the cell 108 and sucks the pseudo sample and then moves up to move to the outside of the cell 108, the cell 108, and hence the calibration package 100, also tends to move up with the suction nozzle. There is. Even in such a case, since the top plate 34 covers a part of the calibration package 100, the separation of the calibration package 100 from the rack body 12 is prevented.

  Next, the merit of using such a rack will be described. As described above, the calibration package 100 is used for calibration processing of the measuring apparatus, and each cell 108 contains a pseudo sample whose characteristic value is known. In the calibration process, the pseudo sample accommodated in each cell 108 of the calibration package 100 is measured with a measuring device in the same manner as a normal sample, and the obtained measurement result is compared with a known characteristic value. In order to perform such a calibration process easily, it is desirable that the pseudo sample can be handled in the same manner as a normal sample.

  Here, handling of a normal sample will be briefly described with reference to FIGS. 7 and 8. Each normal sample is accommodated in a sample container 120 such as a test tube. As shown in FIG. 7, the sample side bar code 122 indicating the identification information of the contained sample is usually attached to the outer surface of each sample container 120.

  The sample containers 120 are held upright by a sample rack 130 every predetermined number. The sample rack 130 is formed with an opening 132 for enabling the sample-side barcode 122 attached to each sample container 120 to be observed from the front side of the sample rack 130. A rack side bar code 134 indicating identification information of the rack 130 is attached to one side surface of the sample rack 130.

  The sample container 120 held upright by the sample rack 130 is set in the standby unit 150 of the measuring apparatus together with the sample rack 130 as shown in FIG. The racks set in the standby unit 150 are taken out one by one by a transport mechanism provided in the measurement apparatus and transported to the measurement unit. Two barcode readers 140 and 142 are provided in the middle of the transport path. The rack-side reader 142 is installed on the back side of the sample rack 130 to be transported, and reads the rack-side barcode 134 attached to one end surface of the sample rack 130. The sample side reader 140 is installed on the front side of the sample rack 130 to be transported, and reads the sample side barcode 122 attached to each sample container 120. Then, a control unit (not shown) of the measuring apparatus identifies each sample based on the results read by the two bar code readers 140 and 142, and determines subsequent processing contents.

  When calibrating the measuring apparatus, a pseudo sample is used instead of a normal sample. However, in order to simplify the processing, it is desirable that this pseudo sample is handled in the same manner as a normal sample.

  Therefore, in the present embodiment, the calibration package 100 is held upright by the special-shaped package rack 10 and the calibration package 100 is set in the measuring apparatus together with the rack 10. As described above, the package rack 10 of the present embodiment has the same size as the normal sample rack 130 and has the T-shaped groove 16 that can be engaged with the rail provided in the transport mechanism. ing. With such a configuration, the package rack 10 and the calibration package 100 (and thus the pseudo sample) held upright by the package rack 10 can be measured similarly to the normal sample rack 130 and the sample container 120. It becomes possible to carry by the carrying mechanism provided in the.

  Further, like the normal sample, the calibration package 100 is desirably identified by the control unit of the measuring apparatus. In order to satisfy such a demand, in this embodiment, a rack-side barcode 28 indicating identification information of the package rack 10 is attached to one side end surface of the package rack 10. The rack-side barcode 28 can be read by a rack-side reader 142 provided in the vicinity of the conveyance path.

  In the present embodiment, the package rack 10 is provided with a mirror 24 as a reflecting material so that the package-side barcode 110 attached to each calibration package 100 can also be read. As described above, the mirror 24 is set to have an acute angle with the side wall 104 to which the package-side bar code 110 is attached, more specifically about 45 degrees. As a result, the package side barcode 110 can be read by the sample side reader 140 in the same manner as the sample side barcode 122 attached to the normal sample container 120.

  That is, the sample side reader 140 that reads the sample side barcode 122 attached to the sample container 120 is disposed on the front side of the package rack 10 that is transported by the transport mechanism. On the other hand, the package-side barcode 110 attached to the calibration package 100 is attached to the side wall 104 of the calibration package 100 and cannot be observed from the front side as it is. However, the package rack 10 of this embodiment has a mirror 24 that is inclined with respect to the package-side barcode 110. As shown in FIG. 6, the mirror 24 bends the image light 110a of the package side barcode 110 to the front side where the sample side reader 140 is disposed. As a result, the package side barcode 110 can be read by the sample side reader 140. As a result, the calibration package 100 can be identified without newly providing a dedicated barcode reader. In other words, by using the package rack 10 of the present embodiment, the calibration package 100 can be handled in the same way as a normal sample without adding a special configuration to the measurement apparatus, and as a result, calibration. Processing can be performed easily.

  DESCRIPTION OF SYMBOLS 10 Package rack, 12 Rack main body, 14 Lid body, 16-shaped groove, 18 receiving recessed part, 20 Level | step difference surface, 22 Reflecting part, 24 Mirror, 26 Locking hole, 28 Rack side barcode, 30 Front plate, 32 Back plate, 34 Top plate, 36 Confirmation window, 38 Engagement claw, 40 Rotating shaft, 42 Passing opening, 100 Calibration package, 102 Main body, 104 Side wall, 106 Front wall, 108 cell, 110 Package side barcode, 112 Character information , 120 sample container, 122 sample side barcode, 130 sample rack, 132 opening, 134 rack side barcode, 140 sample side reader, 142 rack side reader, 150 standby section.

Claims (3)

A package rack for holding a calibration package in which a plurality of calibration fluids are individually stored;
The calibration package is
A main body unit in which a plurality of cells each containing a calibration fluid are connected side by side;
A side wall extending at least downward from one side end of the cell body in the cell arrangement direction, and a side wall with a package side identification image indicating identification information of the calibration package added to the surface thereof;
If you have
The package rack is
An accommodating recess for standing and holding the plurality of cells in a state where the side wall is located on the outside;
A reflective material that is opposed to the side wall at an angle that makes an acute angle with the side wall when viewed from above, and that bends the optical path of the image light of the package side identification image in a horizontal plane;
A rack characterized by comprising: The rack of claim 1, further comprising:
A rack, comprising: a lid that can be switched between an open state that allows detachment of the cell from the receiving recess and a closed state that prevents detachment of the cell from the receiving recess. The rack according to claim 2,
The rack according to claim 1, wherein the lid includes an opening that exposes a part of the upper surface of each cell to the outside in the closed state.

Images