JP3688663B2 - Sample transfer device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sample transfer apparatus for transferring a container for storing a sample held in a rack to another rack.
[0002]
[Prior art]
Conventionally, in a dispensing device that automatically dispenses a sample (sample) or a sample analyzer that automatically analyzes a sample, each sample is stored in a tube-like container such as a test tube. A plurality of units are held in a small rack that holds them in a line and are transported for each rack.
[0003]
In addition, when storing samples, a large rack that holds a large number of containers arranged in a matrix is used.
[0004]
For this reason, for example, when storing the remaining parent sample that has been dispensed by the dispensing device for analysis by the sample analyzer, the container held in the small rack is transferred to the large rack. Is done.
[0005]
However, heretofore, there has been no device for transferring a container for storing a sample held in a rack to another rack. For this reason, transferring containers held in a rack to another rack relies on humans, so that, for example, when a large number of specimens are processed in a hospital or laboratory, it takes a lot of time and effort. was there.
[0006]
[Problems to be solved by the invention]
An object of the present invention is to provide a sample transfer device capable of smoothly and surely transferring a container for storing a sample held in a rack to another rack.
[0007]
[Means for Solving the Problems]
Such an object is achieved by the present inventions (1) to ( 12 ) below.
[0008]
(1) A tube-like container for storing a sample is held in a first rack that holds a plurality of the containers, and the containers are arranged in n rows × m columns (where n and m are integers of 2 or more, respectively). A sample transfer device for transferring to and from the second rack,
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism at least in the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container .
[0009]
(2) A tube-like container for storing a sample, a first rack for holding a plurality of the containers arranged in one row, and the containers in n rows × m columns (where n and m are integers of 2 or more, respectively) A specimen transfer device that transfers between the second racks arranged side by side and
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism at least in the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container .
[0010]
(3) A tube-like container for storing a sample, a first rack that holds the n containers (where n is an integer of 2 or more) arranged in a row, and the containers are n rows × m columns (however, m is an integer greater than or equal to 2), and is a sample transfer device that transfers between the second racks that are held side by side,
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism in a two-dimensional direction including at least the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container .
[0011]
(4) The specimen transfer device according to any one of (1) to (3), wherein the restriction member covers an upper end opening of the container whose posture is restricted.
[0012]
(5) The gripping mechanism includes at least one pressing member that presses the outer peripheral surface of the container, a flat plate member that sandwiches the container between the pressing member, and the pressing member that is used as the plate member. The specimen transfer apparatus according to any one of (1) to (4), further including a driving unit that approaches and separates the specimen from the specimen.
[0013]
(6) The specimen transfer device according to (5), wherein an opening is formed at a position corresponding to the container of the plate member.
[0014]
(7) The specimen transfer according to (5) or (6), further including a pressing force stabilizing unit that maintains a pressing force of the pressing member against the container regardless of an outer diameter of the container gripped by the gripping mechanism. Mounting device.
[0015]
(8) The gripping mechanism includes a biasing member that generates a pressing force of the pressing member against the container by its elastic force.
The pressing force stabilizing means has deformation amount detecting means for detecting that the amount of deformation of the biasing member becomes a predetermined amount, and the deformation amount detecting means detects when the gripping mechanism grips the container. The specimen transfer apparatus according to (7), wherein the operation of the driving unit is controlled so that the amount of deformation of the biasing member becomes a predetermined amount according to a result.
[0016]
(9) The specimen transfer device according to (8), wherein the deformation amount detection means optically detects that the deformation amount of the biasing member reaches a predetermined amount.
[0017]
(10) The deformation amount detection unit includes a light projecting unit, a light receiving unit that can receive light emitted from the light projecting unit, and a displacement unit that is displaced according to the deformation amount of the biasing member. ,
The displacement portion is installed to block light emitted from the light projecting portion when the deformation amount of the biasing member reaches a predetermined amount,
The deformation amount detecting means detects that the deformation amount of the urging member becomes a predetermined amount when the light receiving unit changes from a state of receiving the light emitted from the light projecting unit to a state of not receiving the light. The specimen transfer device according to (9).
[0018]
(11) The sample transfer device according to any one of (1) to (10), further including a transport mechanism that transports the first rack.
[0019]
(12) The sample transfer apparatus according to any one of (1) to (11), further including a transport mechanism that transports the second rack.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a sample transfer device of the present invention will be described in detail based on a preferred embodiment shown in the accompanying drawings.
[0023]
1 is a plan view showing an embodiment of the sample transfer apparatus of the present invention, FIG. 2 is a perspective view showing a gripping mechanism in the sample transfer apparatus shown in FIG. 1, and FIGS. FIG. 6 is a perspective view showing a guide member and a second rack in the sample transfer apparatus shown in FIG. 1, and FIGS. FIG. 15 is a schematic block diagram of the sample transfer device shown in FIG. 1. FIG. 15 is a cross-sectional side view showing the configuration and operating state of the sample transfer device shown in FIG.
[0024]
The sample transfer apparatus 1 shown in FIG. 1 is an apparatus that transfers a tube-shaped container 300 that stores a sample held in a first rack 100 to a second rack 200. The apparatus main body 2 and a plurality of containers 300 are transferred. A holding mechanism 3 that can hold the holding mechanism 3 at the same time, a moving means 4 that moves the holding mechanism 3, and a regulating means that regulates the posture of the container 300 held in the second rack 200 adjacent to the row to be transferred. 5, a first rack transport mechanism 11 that transports the first rack 100, a second rack transport mechanism 12 that transports the second rack 200, and a barcode label (first information carrier) 301 attached to the container 300. A container barcode reader (first reading device) 13 for reading information carried and a second rack for reading information carried by a barcode label (second information carrier) 201 attached to the second rack 200. A bar code reader (second reader) 14, and a reflective sensor 6 for projecting and receiving with respect to the container 300.
[0025]
The container 300 is a container such as a test tube having a tubular shape (bottomed cylindrical shape) that is long in the vertical direction. The container 300 contains (accommodates) a specimen (for example, body fluid such as blood and blood components). In the configuration shown in the drawing, the container 300 has a flange 302 formed so as to protrude over the entire periphery of the upper end opening (see FIG. 2). There are a plurality of types of containers 300 having different lengths (see FIG. 14).
[0026]
As shown in FIG. 6, on the outer peripheral surface of the container 300, (corresponding) information (for example, sample ID number, patient ID number, patient name, hospital name, blood sampling date, container ID number, etc.) about the stored sample A bar code label 301 to which a bar code carrying “” is attached is attached. Note that the bar code label 301 is not shown in the drawings other than FIG.
[0027]
The first rack 100 is configured such that a plurality (ten in this embodiment) of containers 300 can be held in a line in the longitudinal direction of the first rack 100 in a standing state (standing state). That is, in the first rack 100, ten concave portions (holes) 101 into which the lower portion of the container 300 is inserted are arranged in a line.
[0028]
In the first rack 100, the height of the bottom of the recess 101 is adjusted according to the length of the container 300 so that the height of the upper end of the stored container 300 is substantially the same regardless of the difference in the length of the container 300. ing. For example, the first rack 100 that houses the container 300 having a relatively short length shown in FIG. 11 has a bottom of the recess 101 higher than the first rack 100 that houses the container 300 having a relatively long length shown in FIG. The bottom is raised). A single first rack 100 stores a plurality of containers 300 of the same type (equal length).
[0029]
As shown in FIG. 6, the second rack 200 is arranged in a matrix (10 rows × 5 columns in this embodiment) in a state in which a plurality (50 in this embodiment) of containers 300 are erected (standing state). It is configured to be able to hold. That is, 50 concave portions (holes) 203 into which the lower portion of the container 300 is inserted are formed in the second rack 200 in 10 rows × 5 columns. The arrangement pitch of the concave portions 203 in the row direction of the second rack 200 is equal to the arrangement pitch of the concave portions 101 of the first rack 100. That is, the arrangement pitch of the containers 300 held in the first rack 100 is equal to the arrangement pitch of the containers 300 held in the second rack 200 in the column direction.
[0030]
On the side surface of the second rack 200, a barcode label 201 to which a barcode carrying information for identifying the second rack 200 (for example, a rack ID number) is attached is attached. In the drawings other than FIG. 6, the barcode label 201 is not shown.
[0031]
As shown in FIG. 1, the apparatus main body 2 is provided with a first rack transport mechanism 11 that transports the first rack 100 in the longitudinal direction thereof. The first rack transport mechanism 11 is composed of, for example, a belt transport mechanism (belt conveyor).
[0032]
A first rack supply unit (not shown) for storing a plurality of first racks 100 holding the containers 300 is provided on the upstream side (left side in FIG. 1) of the first rack transport mechanism 11. The held first rack 100 is supplied from the first rack supply unit to the first rack transport mechanism 11.
[0033]
The first rack 100 supplied to the first rack transport mechanism 11 is transported in the right direction in FIG. 1 and is temporarily stopped by the operation of a rack stopper mechanism (not shown) when it reaches a predetermined stop position 21. At the stop position 21, the container 300 held by the first rack 100 is transferred to the second rack 200 by the operation of the gripping mechanism 3 and the moving unit 4 described later. After the transfer, the empty first rack 100 is further transported to the right in FIG. 1 and discharged by the operation of the first rack transport mechanism 11.
[0034]
In the apparatus main body 2, a second rack transport mechanism 12 that transports the second rack 200 along the longitudinal direction thereof is installed so as to be parallel (parallel) to the first rack transport mechanism 11. The second rack transport mechanism 12 is composed of, for example, a belt transport mechanism (belt conveyor).
[0035]
A second rack supply unit 22 for storing a plurality of empty second racks 200 is provided adjacent to the upstream side of the second rack transport mechanism 12 (left side in FIG. 1). The second rack 200 stored in the second rack supply unit 22 is pushed upward in FIG. 1 by the operation of a push mechanism (not shown), and is sequentially supplied to the upstream part of the second rack transport mechanism 12. The traveling direction of the second rack 200 in the second rack supply unit 22 is substantially perpendicular to the transport direction of the second rack transport mechanism 12.
[0036]
The empty second rack 200 supplied to the upstream portion of the second rack transport mechanism 12 is transported in the right direction in FIG. 1 and is temporarily stopped by a rack stopper mechanism (not shown) when it reaches a predetermined stop position 23. Be made. The container 300 held by the first rack 100 is transferred to the second rack 200 stopped at the stop position 23.
[0037]
The stop position 23 corresponds to the stop position 21 of the first rack 100, and the second rack 200 stopped at the stop position 23 and the first rack 100 stopped at the stop position 21 are in the transport direction. Located at approximately the same position.
[0038]
When the transfer is completed, the second rack 200 holding the container 300 is further transported in the right direction in FIG. 1 by the operation of the second rack transport mechanism 12.
[0039]
A second rack discharge section 24 that stores a plurality of second racks 200 holding the transferred containers 300 is provided adjacent to the downstream side of the second rack transport mechanism 12 (the right side in FIG. 1). . The second rack 200 transported to the downstream portion of the second rack transport mechanism 12 is pushed downward in FIG. 1 by the operation of a push mechanism (not shown) and discharged to the second rack discharge section 24. The traveling direction of the second rack 200 in the second rack discharge unit 24 is substantially perpendicular to the transport direction of the second rack transport mechanism 12.
[0040]
A container barcode reader 13 for reading information carried by the barcode label 301 attached to the container 300 is installed on the upstream side of the first rack transport mechanism 11. The container barcode reader 13 is a barcode of each container 300 held by the first rack 100 when the first rack 100 conveyed by the first rack conveyance mechanism 11 passes through the container barcode reader 13. Each label 301 is read.
[0041]
On the upstream side of the second rack transport mechanism 12, a second rack barcode reader 14 that reads information carried by the barcode label 201 attached to the second rack 200 is installed. The second rack barcode reader 14 reads the barcode label 201 of the second rack 200 when the second rack 200 is supplied from the second rack supply unit 22 to the upstream portion of the second rack transport mechanism 12. I do.
[0042]
As shown in FIG. 5, the gripping mechanism (gripping mechanism) 3 in the present embodiment is capable of simultaneously gripping ten containers 300 arranged in a row, and a pressing member 31 that presses the outer peripheral surface of the container 300. 10 parts having a flat plate member 32 that sandwiches the container 300 with the pressing member 31 are arranged side by side. Since ten portions corresponding to each container 300 in the gripping mechanism 3 have the same configuration, only one of them will be described below as a representative.
[0043]
As shown in FIG. 2, the pressing member 31 has a substantially V-shaped recess (notch) 311 at the contact portion with respect to the container 300, and two planes constituting the recess 311 are near the upper end of the container 300. It contacts (contacts) the outer peripheral surface of the. Since the pressing member 31 has the recess 311, the gripping mechanism 3 can securely hold the container 300 without play (rattle), and in particular, the recess 311 is substantially V-shaped, Regardless of the outer diameter, the container 300 can be reliably gripped without play (rattle).
[0044]
The ten pressing members 31 are both supported by a single plate-like support member 33. The support member 33 is installed in a posture substantially parallel to the plate member 32. On the side opposite to the recess 311 of each pressing member 31, two rod-shaped pins 30 are provided so as to protrude. By inserting the pins 30 into the through holes 331 formed in the support member 33, A support member 33 supports each pressing member 31. Each pressing member 31 is movable with respect to the support member 33 when the pin 30 slides in the through hole 331.
[0045]
Between the pressing member 31 and the support member 33, a coil spring (biasing member) 34 that urges the pressing member 31 in the pressing direction with respect to the container 300 is installed. In the illustrated configuration, the coil springs 34 are installed with the pins 30 inserted inside, and two coil springs 34 are provided for each pressing member 31.
[0046]
The plate member 32 is a flat plate member. In the present embodiment, the plate member 32 has an escape portion (opening) 321 into which the flange 302 can be inserted at a position corresponding to the flange 302 of the container 300. Accordingly, even when the container 300 having the flange 302 is gripped, the flange 302 does not get in the way, and the plate member 32 reliably contacts the outer peripheral surface near the upper end of the container 300. The container 300 can be securely gripped.
[0047]
The plate member 32 is fixed to the frame 35 of the gripping mechanism 3. In the illustrated configuration, the plate members 32 for the ten containers 300 are integrally formed, but the plate members 32 may be divided into a plurality of pieces.
[0048]
In addition, the part which contacts the container 300 of the press member 31 and the plate member 32 may be coat | covered with elastic materials, such as rubber | gum, for example as a slip prevention means.
[0049]
In such a gripping mechanism 3, of the pressing member 31 and the plate member 32 that sandwich the container 300, the protruding width from the container 300 is almost only the plate thickness of the plate member 32 on the plate member 32 side, and is extremely small. . Then, when transferring the containers 300 gripped by the gripping mechanism 3 to the second rack 200 one by one, the sample transfer apparatus 1 arranges the containers 300 in order from the row on the plate member 32 side (FIG. 13, (See FIG. 14). Thus, even when the gap 400 between the container 300 in the next row held (already transferred) held in the second rack is narrow, the gripping mechanism 3 (plate member 32) is placed in the container 300 in the next row. There is no contact or interference. Therefore, the sample transfer apparatus 1 transfers the container 300 even when the interval between the rows of the containers 300 held by the second rack 200 (the interval between the rows of the recesses 203) is relatively small. Replacement can be performed smoothly.
[0050]
The support member 33 is installed so as to be movable with respect to the frame 35 by being guided by a guide shaft (not shown) provided in the frame 35. As shown in FIGS. 3 to 5, the support member 33 moves so as to approach and separate from the plate member 32 fixed to the frame 35.
[0051]
As shown in FIG. 7, the frame 35 is provided with driving means 36 that opens and closes the gripping mechanism 3 by moving the support member 33. The drive means 36 includes a feed screw 361 that moves the support member 33 and a gripping mechanism opening / closing motor 363 that rotates the feed screw 361 via a belt 362. When the output shaft of the gripping mechanism opening / closing motor 363 rotates in a predetermined direction, the support member 33 and all the pressing members 31 move so as to approach the plate member 32 (see FIG. 8), and the output of the gripping mechanism opening / closing motor 363 When the shaft rotates in the reverse direction, the support member 33 and all the pressing members 31 move away from the plate member 32.
[0052]
When gripping (holding) the container 300 with the gripping mechanism 3, as shown in FIG. 3, the pressing member 31 and the plate member 32 are separated from each other, and the upper end portion of the container 300 is positioned between them. Is done. When no grabbing of the container 300, the length of the coil spring 34 is adapted to L ₁ of the natural length. Note that the pin 30 is prevented from coming out of the through-hole 331 beyond the state shown in FIG. 3 because a not-shown locking portion is locked to the support member 33, whereby the pressing member 31 is The support member 33 is not separated.
[0053]
When the gripping mechanism opening / closing motor 363 is operated from the state shown in FIG. 3 to bring the support member 33 closer to the plate member 32, the pressing member 31 and the plate member 32 are connected to the outer peripheral surface of the container 300 as shown in FIG. The container 300 is sandwiched between the pressing member 31 and the plate member 32.
[0054]
When the gripping mechanism opening / closing motor 363 is further operated from the state shown in FIG. 4 to bring the support member 33 closer to the plate member 32, the distance between the pressing member 31 and the support member 33 is reduced, as shown in FIG. a coil spring 34 is compressed, its length shrinks L _2. In the state shown in FIG. 5, the container 300 is firmly held between the pressing member 31 and the plate member 32 by the elastic force (pressing force) of the coil spring 34. At this time, the magnitude of the pressing force (gripping force) by which the pressing member 31 presses the container 300 is K (L ₁ −L ₂ ) × 2 where K is the spring constant of the coil spring 34. The coil spring 34 may be installed in a compressed state in the initial state of FIG. 3 where the container 300 is not gripped. In this case, the pressing force (gripping force) when gripping the container 300 is K ( L ₁ −L ₂ ) × 2 is a value obtained by adding the elastic force (pressing force) in the initial state of the coil spring 34.
[0055]
In the state shown in FIG. 5, the protrusion length of the pin 30 toward the back surface side of the support member 33 (the side opposite to the side where the pressing member 31 is installed) becomes long.
[0056]
Such a gripping mechanism 3 can simultaneously grip ten containers 300 as shown in FIG. That is, in the present embodiment, the gripping mechanism 3 can simultaneously grip the same number of containers 300 as the number of containers 300 that can be held by the first rack 100 and the number of rows of containers 300 that can be held by the second rack 200. Therefore, the sample transfer apparatus 1 can further improve the transfer efficiency and transfer the container 300 at a higher speed. Further, since the transfer can be performed by moving the gripping mechanism 3 only in the two-dimensional direction, the moving means 4 described later does not need to move the gripping mechanism 3 in the arrangement direction of the containers to be gripped. The structure of the moving means 4 can be simplified.
[0057]
Further, even when the gripping mechanism 3 has 1 to 9 containers 300 (when only 1 to 9 containers 300 are contained in the first rack 100), it can simultaneously grip them. . Further, since the pressing member 31 and the coil spring 34 are individually provided for each container 300, the pressing force (gripping force) of the pressing member 31 against each container 300 can be increased regardless of the number of containers 300 to be gripped. It can be made constant (same as when there are 10 containers 300).
[0058]
The sample transfer device 1 has moving means 4 for moving such a gripping mechanism 3 in a two-dimensional direction including the longitudinal direction of the container 300. The moving means 4 includes a gripping mechanism lifting mechanism 41 that moves the gripping mechanism 3 in the longitudinal direction of the container 300, that is, a vertical direction (vertical direction), and a grip that moves the gripping mechanism 3 in the horizontal direction (vertical direction in FIG. 1). And a mechanism horizontal movement mechanism 42.
[0059]
As shown in FIG. 7, the gripping mechanism lifting mechanism 41 includes a support column 411 and a bracket 412 that can move in the vertical direction along the support column 411. A frame 35 of the gripping mechanism 3 is fixed to the bracket 412. The support 411 is provided with a mechanism (not shown) such as a feed screw and a rack and pinion gear, and a motor (not shown) for driving the mechanism, and the bracket 412 is moved by the operation of these mechanisms. It can be moved up and down. Thereby, the gripping mechanism lifting mechanism 41 moves the gripping mechanism 3 in the vertical direction.
[0060]
As shown in FIGS. 1 and 7, the gripping mechanism horizontal movement mechanism 42 is installed near both sides of the apparatus main body 2, and extends between the rails 421 and 422 that are parallel to each other and the rails 421 and 422. It has a moving beam 423 that is installed so as to be passed and is in a posture perpendicular to the rails 421 and 422. The rails 421 and 422 are installed at a height separated from the upper surface of the apparatus main body 2 by a predetermined distance so as not to interfere with the first rack 100 and the like transported by the first rack transport mechanism 11. The lower end of the support column 411 of the gripping mechanism lifting mechanism 41 is fixed to the center of the moving beam 423.
[0061]
The gripping mechanism horizontal movement mechanism 42 includes a mechanism (not shown) such as a feed screw and a rack and pinion gear, and a motor (not shown) that drives the mechanism, and by these operations, the moving beam 423 is operated. Can be moved along the rails 421 and 422. That is, the moving beam 423 moves in the direction perpendicular to the longitudinal direction thereof, and the holding mechanism lifting mechanism 41 and the holding mechanism 3 move in the lateral direction in FIGS. 7 to 14 along with the moving beam 423.
[0062]
As shown in FIG. 1, a reflection sensor 6 that projects and receives light on the container 300 is installed in the vicinity of the first rack 100 stopped at the stop position 21. The reflection sensor 6 performs optical detection while the light projecting unit 61 and the light receiving unit 62 move in the longitudinal direction of the container 300 relative to the container 300, whereby the gripping mechanism 3 grips the container 300. It functions as a length detection means for detecting the length.
[0063]
In the present embodiment, the reflection sensor 6 is provided for each of the ten containers 300 held in the first rack 100. That is, ten reflection sensors 6 are installed. Since these reflection sensors 6 have the same configuration, one of them will be described as a representative.
[0064]
As shown in FIG. 7, the reflection sensor 6 includes a light projecting unit 61 and a light receiving unit 62 positioned above the upper end of the first rack 100 stopped at the stop position 21, and a sensor main body 63 incorporating the light emitting element and the light receiving element. And an optical fiber 64 that connects the light projecting unit 61 and the light receiving unit 62 to the sensor main body 63. In the illustrated configuration, the light projecting unit 61 and the light receiving unit 62 are integrally configured. The reflection sensor 6 transmits the light emitted from the light emitting element in the sensor main body 63 to the light projecting unit 61 through the optical fiber 64, projects the light from the light projecting unit 61, and irradiates the outer peripheral surface of the container 300. The reflection sensor 6 receives the reflected light reflected by the outer peripheral surface of the container 300 by the light receiving unit 62, guides the light to the light receiving element in the sensor main body 63 through the optical fiber 64, and performs photoelectric conversion.
[0065]
Such a reflection sensor 6 is configured such that when the container 300 gripped by the gripping mechanism 3 is lifted from the first rack 100 by the operation of the gripping mechanism lifting mechanism 41, the light projecting unit 61 and the light receiving unit 62 are relative to the container 300. The length of the container 300 (the length below the position (gripping position) gripped (clamped) by the gripping mechanism 3) is detected by performing optical detection while moving in the longitudinal direction of the container 300.
[0066]
With this configuration, in this embodiment, the length of the container 300 can be detected with a simple structure, and the structure can be simplified and downsized, and the manufacturing cost can be reduced.
[0067]
In the present embodiment, the reflection sensor 6 is individually provided for each of the ten containers 300 that can be held by the first rack 100, so that the container 300 is included in the ten recesses 101 of the first rack 100. If there is a place where the container 300 is not held, the length of the container 300 can be detected even when only one container 300 is held in the first rack 100.
[0068]
In the present embodiment, the light projecting unit 61 and the light receiving unit 62 of the reflection sensor 6 are fixedly installed on the apparatus main body 2, but can be moved in the longitudinal direction of the container 300 gripped by the gripping mechanism 3. It may be installed.
[0069]
The length detection means for detecting the length of the container 300 is not limited to the configuration of the present embodiment. For example, the container 300 is imaged (captured) with an image sensor and the image is processed (analyzed). For example, the length of the container 300 may be detected by touching the container 300, or the length of the container 300 may be mechanically detected by touching the container 300.
[0070]
As shown in FIG. 1, the restricting means 5 is installed near the second rack 200 stopped at the stop position 23. The regulating means 5 regulates the posture of the container 300 held in the row adjacent to the row to be transferred in the second rack 200, that is, the posture of the container 300 that has already been transferred to the second rack 200 (first). And a regulating member 51 that can abut (contact) the container 300 whose posture is to be regulated, and a regulating member moving mechanism 52 that moves the regulating member 51.
[0071]
As shown in FIG. 11, the restricting member 51 is a plate-like contact portion 511 that is in a posture along the row direction of the containers 300 held by the second rack 200 stopped at the stop position 23 and substantially perpendicular to the horizontal plane. And a cover portion 512 extending substantially horizontally from the upper end portion of the contact portion 511. The regulating member 51 has substantially the same width as the length of the second rack 200 in the longitudinal direction, and simultaneously regulates the posture of one row (ten) of containers 300 in the second rack 200.
[0072]
The restricting member moving mechanism 52 has a built-in mechanism (not shown) such as a feed screw and a rack and pinion gear, and a motor (not shown) for driving the built-in mechanism. The regulating member 51 can be moved in the vertical direction (vertical direction) and in the horizontal direction (lateral direction in FIGS. 7 to 14).
[0073]
As shown in FIG. 13 and FIG. 14, when the container 300 gripped by the gripping mechanism 3 is transferred to the second rack 200, the regulating means 5 is held in a row next to the row to be transferred in the second rack 200. The inner surface of the contact portion 511 is brought into contact with the side portion of the container 300 (the outer peripheral surface of the flange 302 or the body portion of the container 300), and the containers 300 in the adjacent rows are regulated so as to be drawn to the right in the drawing. The member moving mechanism 52 is operated. As a result, the container 300 held in the row adjacent to the second rack 200 is in its posture (inclined direction) so as to be separated from the container 300 that is being transferred (gripped by the grasping mechanism 3). ) Is regulated.
[0074]
In the state shown in FIG. 13, the regulating means 5 regulates the posture of the container 300 in the rightmost row in the figure in order to perform transfer to the second row from the right side in the figure of the second rack 200. Similarly, when the second rack 200 is transferred to the third, fourth, and fifth rows from the right side in the drawing, the second, third, and third rows from the right side in the drawing, respectively. The posture of the container 300 held in the fourth row is regulated.
[0075]
By providing such a regulating means 5, when the container 300 is transferred, the container 300 held in the row adjacent to the row to be transferred in the second rack 200, the gripping mechanism 3, or the gripping mechanism 3. It is possible to more reliably prevent contact and interference with the container 300 held by the container, and the container can be transferred smoothly and reliably.
[0076]
Moreover, in this embodiment, since the regulating member 51 has the cover part 512, the cover part 512 covers the upper end opening of the container 300 whose attitude is regulated. As a result, even if the specimen stored in the container 300 being transferred jumps due to an impact during movement or the like, the splash is mixed into another container 300 held in the second rack 200. Can be prevented, and contamination can be surely prevented.
[0077]
As shown in FIG. 15, the sample transfer device 1 includes a control unit 15 to which each part of the sample transfer device 1 as described above is connected. The control means 15 has a CPU (Central Processing Unit) and a sequencer, and is configured in software and hardware. Note that a storage unit (storage unit) 71, a display unit 72, and an operation unit (input unit) 73 are further connected to the control unit 15.
[0078]
The storage unit 71 has a storage medium (recording medium) that can be read by the control means 15 and stores (records) programs, data, and the like. This storage medium includes, for example, RAM (Random Access Memory: including both volatile and nonvolatile), FD (Floppy Disk (“Floppy” is a registered trademark)), HD (Hard Disk), CD-ROM (Compact It is composed of a magnetic or optical recording medium such as a disc read-only memory or a semiconductor memory. This storage medium is fixedly attached to the storage unit 71 or is detachably mounted. In this storage medium, various application programs corresponding to each part of the sample transfer device 1, as described later, are provided. Various programs such as a program for executing the control operation of the sample transfer device 1 and various data are stored in advance, data processed by each program, input data from each unit connected to the control means 15, and the like Is memorized.
[0079]
The control unit 15 reads various programs and data stored in the storage unit 71 as necessary, and controls the operation of each unit of the sample transfer device 1 based on the program and data.
[0080]
Note that the control means 15 may be configured entirely by software without having a sequencer, or may be configured by hardware so that all is performed by sequence control using only the sequencer.
[0081]
The first rack transport mechanism 11 and the second rack transport mechanism 12 are respectively connected to the control means 15, and the control means 15 controls the operations of the first rack transport mechanism 11 and the second rack transport mechanism 12, respectively. .
[0082]
Each of the container barcode reader 13 and the second rack barcode reader 14 is connected to the control means 15. The container barcode reader 13 and the second rack barcode reader 14 output the information read from the barcode label 301 and the barcode label 201 to the control means 15, respectively.
[0083]
The control means 15 stores the information input from the container barcode reader 13 and the second rack barcode reader 14 in the storage unit 71. These pieces of information are used for creating management data (management information) to be described later.
[0084]
The reflection sensor 6 is connected to the control unit 15, and projects light from the light projecting unit 61 to the outer peripheral surface of the container 300 according to an instruction from the control unit 15, and the reflected light is received by the light receiving unit 62. A signal obtained by photoelectric conversion by the light receiving element is output to the control means 15.
[0085]
The gripping mechanism opening / closing motor 363 of the gripping mechanism 3 is connected to the control means 15 via a driver (drive circuit) 75, and the control means 15 operates the gripping mechanism opening / closing motor 363 via the driver 75. To control.
[0086]
The gripping mechanism lifting mechanism 41 is connected to the control means 15, and the control means 15 controls the operation of the gripping mechanism lifting mechanism 41. The motor that drives the gripping mechanism lifting mechanism 41 is configured by a pulse motor (stepping motor), and the control unit 15 controls the gripping mechanism lifting mechanism 41 by open loop control. That is, the control means 15 grasps the vertical position (height) of the gripping mechanism 3 by monitoring the number of drive pulses for the motor that drives the gripping mechanism lifting mechanism 41. Note that the present invention is not limited to this configuration, and a detector that detects the vertical position of the gripping mechanism 3 may be provided, and the control unit 15 may control the gripping mechanism lifting mechanism 41 by closed loop control.
[0087]
The holding mechanism horizontal movement mechanism 42 is connected to the control means 15, and the control means 15 controls the operation of the holding mechanism horizontal movement mechanism 42. The motor that drives the gripping mechanism horizontal movement mechanism 42 is a pulse motor (stepping motor), and the control unit 15 controls the gripping mechanism horizontal movement mechanism 42 by open loop control. That is, the control means 15 grasps the position of the gripping mechanism 3 in the horizontal direction by monitoring the number of drive pulses for the motor that drives the gripping mechanism horizontal movement mechanism 42. Not limited to this configuration, a detector for detecting the horizontal position of the gripping mechanism 3 may be provided, and the control unit 15 may control the gripping mechanism horizontal movement mechanism 42 by closed loop control.
[0088]
The restriction member moving mechanism 52 is connected to the control means 15, and the control means 15 moves the restriction member 51 by controlling the operation of the restriction member moving mechanism 52.
[0089]
The display unit 72 includes, for example, a CRT (Cathode-Ray Tube), a liquid crystal display, and the like, and displays an operation screen, a data input screen, and the like, for example.
[0090]
The operation unit 73 includes, for example, a mouse, a keypad, a keyboard, and the like, and is operated when inputting data.
[0091]
In addition to the sample transfer device 1, the control unit 15 includes a management system 500 that manages the entire sample processing system including various devices such as a dispensing device (not shown) and an analysis device (not shown). It is connected.
[0092]
The control means 15 outputs (transmits) management data (management information), which will be described later, to the management system 500, and the management system 500 stores the management data as it is or edits it as appropriate, not shown. Is stored (recorded) in the unit (storage means).
[0093]
The control means 15 is connected to a light emitting element 81 and a light receiving sensor 82, which will be described later. The light emitting element 81 emits light according to an instruction from the control unit 15 and projects light toward the light receiving sensor 82, and the light receiving sensor 82 outputs a signal obtained by photoelectrically converting the received light to the control unit 15.
[0094]
The specimen transfer apparatus 1 as described above makes the gripping force constant to keep the gripping force of the container 300 (the pressing force of the pressing member 31 against the container 300) constant regardless of the outer diameter of the container 300 gripped by the gripping mechanism 3. Means (pressing force stabilizing means). The gripping force stabilizing means (pressing force stabilizing means) has a deformation amount detecting means 8 for detecting that the deformation amount (contraction amount) of the coil spring 34 becomes a predetermined amount.
[0095]
As shown in FIG. 3, the deformation amount detection means 8 is configured by, for example, an LED or the like installed on the back surface side (the side opposite to the side on which the pressing member 31 is installed) near one end in the longitudinal direction of the support member 33. The light emitting element 81 (light projecting portion), the light receiving sensor 82 (light receiving portion) installed on the back side near the other end in the longitudinal direction of the support member 33, and the deformation amount (shrinkage amount) of the coil spring 34 The light emitting element 81 and the light receiving sensor 82 are composed of a displacement portion 83 that is displaced.
[0096]
The light emitting element 81 emits a light beam R toward the light receiving sensor 82, and the light receiving sensor 82 photoelectrically converts the received light beam R. The light ray R is projected along the arrangement direction of the containers 300 held by the holding mechanism 3.
[0097]
The displacement part 83 is comprised by the front-end | tip part of the pin 30 in the structure of illustration. In a state where the gripping mechanism 3 is not gripping the container 300 (before the deformation of the coil spring 34), the displacement portion 83 is in a position that does not block the light beam R emitted from the light emitting element 81, and the deformation amount (contraction amount) of the coil spring 34 ) Reaches a position that blocks the light ray R when it reaches a predetermined amount (L ₁ -L ₂ ) (see FIG. 5). The displacement part 83 is provided corresponding to each of the ten pressing members 31, and the displacement part 83 corresponding to each pressing member 31 can block the light beam R, respectively.
[0098]
With such a configuration, when the gripping mechanism 3 grips the container 300, the support member 33 further approaches the plate member 32 from the state shown in FIG. 4, whereby the coil spring 34 is compressed and the pin 30 is supported. When protruding from the back surface of the member 33, the displacement portion 83 blocks the light beam R emitted from the light emitting element 81 when the deformation amount (contraction amount) of the coil spring 34 reaches a predetermined amount (L ₁ -L ₂ ). The light receiving sensor 82 does not receive the light beam R (the state shown in FIG. 5). Accordingly, the deformation amount detection means 8 changes the deformation amount (contraction amount) of the coil spring 34 to a predetermined amount (L ₁ −L ₂ ) when the light receiving sensor 82 changes from the state of receiving the light ray R to the state of not receiving the light beam R. Can be detected.
[0099]
When the gripping mechanism 3 grips the container 300, the control unit 15 operates the gripping mechanism opening / closing motor 363 while monitoring the detection signal from the light receiving sensor 82, and detects that the light receiving sensor 82 stops receiving the light beam R. At that time, the gripping mechanism opening / closing motor 363 is controlled to stop. By performing such control, when the gripping mechanism 3 grips the container 300 (the state shown in FIG. 5), the deformation amount (contraction amount) of the coil spring 34 is a predetermined amount (L) regardless of the outer diameter of the container 300. ₁ -L ₂ ). Therefore, regardless of the outer diameter of the container 300, the pressing force (gripping force) of the pressing member 31 against the container 300 is K (L ₁ −L ₂ ) × 2. Thus, in the sample transfer device 1, the pressing force (gripping force) of the pressing member 31 can be kept constant regardless of the outer diameter of the container 300. Thereby, even in the case of the container 300 having a thin outer diameter, the gripping force can be firmly gripped without becoming too weak, and the container 300 can be more reliably prevented from wobbling or falling off. Further, even in the case of the container 300 having a large outer diameter, the gripping force does not become too strong, and the container 300 is not damaged or broken.
[0100]
As described above, in the present embodiment, the gripping force stabilizing means (pressing force stabilizing means) includes the deformation amount detecting means 8 and the control means 15.
[0101]
Such gripping force stabilizing means (pressing force stabilizing means) operates when the displacement portion 83 corresponding to any one of the ten pressing members 31 blocks the light beam R, so that the container to be gripped Even if the number of the 300 is 1 to 9 (when only 1 to 9 containers 300 are contained in the first rack 100), the pressing member 31 is used regardless of the outer diameter of the container 300 as described above. Can be kept constant (K (L ₁ -L ₂ ) × 2).
[0102]
Further, in the present embodiment, the above effect is achieved by providing a set of light emitting element 81 and light receiving sensor 82 instead of providing light emitting element 81 and light receiving sensor 82 for each of ten pressing members 31. Therefore, the structure can be simplified and the manufacturing cost can be reduced.
[0103]
Next, the control operation of the sample transfer device 1 will be described in order based on FIGS.
[0104]
Since the control operation such as reading of information with respect to the barcode labels 301 and 201 has already been described, the description thereof will be omitted.
[0105]
[1] The control unit 15 controls the operations of the first rack transport mechanism 11, the second rack transport mechanism 12, and a rack stopper mechanism (not shown) to stop the first rack 100 holding the container 300 at the stop position 21. The empty second rack 200 is stopped at the stop position 23.
[0106]
[2] As shown in FIG. 7, the control means 15 controls the operation of the gripping mechanism horizontal movement mechanism 42 to move the gripping mechanism 3 above the first rack 100 stopped at the stop position 21. In addition, the gripping mechanism 3 is in a state where the pressing member 31 is separated from the plate member 32 (open state). The container 300 held in the first first rack 100 shown in FIG. 7 is of a type having a relatively long length.
[0107]
[3] As shown in FIG. 8, the control means 15 controls the operation of the gripping mechanism elevating mechanism 41 to lower the gripping mechanism 3 to a predetermined position, and between the pressing member 31 and the plate member 32, the container A portion near the upper end of 300 is positioned. Next, the control unit 15 operates the gripping mechanism opening / closing motor 363 to cause the gripping mechanism 3 to grip the container 300.
[0108]
[4] As shown in FIG. 9, the control unit 15 controls the operation of the gripping mechanism lifting mechanism 41 to raise the gripping mechanism 3 to a predetermined position, lift the container 300, and the concave portion of the first rack 100. Remove from 101. At this time, the reflection sensor 6 projects the outer peripheral surface of the container 300 and receives the reflected light. When the container 300 is lifted and the lower end of the container 300 passes through the positions of the light projecting unit 61 and the light receiving unit 62 of the reflection sensor 6, the reflected light is not detected by the reflection sensor 6. The position of the lower end portion of the container 300 can be detected. The control means 15 monitors such a detection signal from the reflection sensor 6, and determines the length of the container 300 (gripping from the height information of the grasping mechanism 3 when the reflected light is no longer detected by the reflection sensor 6. Information regarding the position below the position (gripping position) gripped (clamped) by the mechanism 3 is obtained, and the length information of the container 300 is stored in the storage unit 71.
[0109]
[5] The control means 15 controls the operation of the gripping mechanism horizontal movement mechanism 42 so that the container 300 gripped by the gripping mechanism 3 is closest to the plate member 32 of the five rows of recesses 203 of the second rack 200 ( The gripping mechanism 3 is moved horizontally so as to be positioned above the concave portions 203 in the row on the right side in the drawing. Next, as shown in FIG. 10, the control unit 15 controls the operation of the gripping mechanism elevating mechanism 41 to lower the gripping mechanism 3, so that the lower side of the container 300 gripped by the gripping mechanism 3 is placed on the second rack 200. Is inserted into the recess 203. At this time, based on the length information of the container 300 detected in [4], the control unit 15 holds the gripping mechanism lifting mechanism 41 so that the lower end of the container 300 stops immediately before the bottom 202 of the second rack 200. Control the operation of Next, the control unit 15 operates the gripping mechanism opening / closing motor 363 to separate the pressing member 31 from the plate member 32 and release the gripping mechanism 3 from gripping the container 300.
[0110]
By performing such control, the sample transfer device 1 can gently (carefully) transfer the container 300 to the second rack 200 regardless of the length of the container 300. That is, the gripping mechanism 3 is lowered too much and the lower end portion of the container 300 collides with the bottom 202 of the concave portion 203 of the second rack 200, or conversely, the gripping mechanism 3 is not sufficiently lowered and the gripping of the container 300 is released. After that, the container 300 does not fall and the lower end of the container 300 does not collide with the bottom 202. Therefore, the impact that the lower end of the container 300 collides with the bottom 202 causes the specimen in the container 300 to jump and drop into the other container 300 to cause contamination, or the container 300 may be damaged. This can be surely prevented.
[0111]
[6] As shown in FIG. 11, the control means 15 operates the gripping mechanism lifting mechanism 41 to raise the gripping mechanism 3 to a predetermined position, and then operates the gripping mechanism horizontal movement mechanism 42 to move the gripping mechanism 3. Move to above the first rack 100.
[0112]
During this time, the control unit 15 operates the first rack transport mechanism 100 to transport and discharge the first empty first rack 100 to the downstream side, and the second first The rack 100 is transported to the stop position 21. The container 300 held in the second first rack 100 shown in FIG. 11 is of a type having a relatively short length.
[0113]
Further, the control means 15 controls the operation of the restricting member moving mechanism 52 to raise the restricting member 51 and then advance it in the horizontal direction toward the second rack 200, so that the portion on the contact portion 511 side Is positioned above the container 300 transferred in [5]. The inner diameter of the recess 203 of the second rack 200 is slightly larger than the outer diameter of the container 300, and there is a gap (play) between the inner peripheral surface of the recess 203 and the outer peripheral surface of the container 300. The container 300 transferred to the second rack 200 in [5] is in a slightly inclined posture in any direction with respect to the vertical direction.
[0114]
[7] As shown in FIG. 12, the control means 15 lowers the gripping mechanism 3 to a predetermined position and grips the container 300 held by the second first rack 100 in the same manner as [3]. Grip to mechanism 3. Further, the control means 15 controls the operation of the restricting member moving mechanism 52 so that the upper end portion of the container 300 transferred to the second rack 200 in [5] is positioned inside the contact portion 511. Then, the regulating member 51 is lowered.
[0115]
[8] As shown in FIG. 13, the control means 15 controls the operation of the gripping mechanism elevating mechanism 41 to raise the gripping mechanism 3 in the same manner as in [4], so that the container 300 is moved to the first rack 100. The length information of the container 300 is obtained based on the detection result of the reflection sensor 6, and the length information is stored in the storage unit 71. The control means 15 controls the operation of the restricting member moving mechanism 52 to move the restricting member 51 in the horizontal direction toward the restricting member moving mechanism 52 side. Thereby, the contact portion 511 contacts the flange 302 of the container 300 transferred to the second rack 200 in [5], and the upper end portions of these containers 300 are drawn toward the regulating member moving mechanism 52 side. The postures of these containers 300 are regulated so as to be inclined so as to move away from the vacant side of the second rack 200 (see FIG. 6).
[0116]
[9] The control means 15 controls the operation of the gripping mechanism horizontal movement mechanism 42 so that the container 300 gripped by the gripping mechanism 3 has already been transferred from the five rows of the recesses 203 of the second rack 200. The gripping mechanism 3 is moved horizontally so as to be positioned above the row adjacent to the row. Next, as shown in FIG. 14, the control means 15 controls the operation of the gripping mechanism elevating mechanism 41 to lower the gripping mechanism 3, so that the lower side of the container 300 gripped by the gripping mechanism 3 is placed on the second rack 200. Is inserted into the recess 203.
[0117]
At this time, since one of the portions of the gripping mechanism 3 that sandwich the container 300 is configured by the plate member 32, even if the gap 400 between the container 300 in the adjacent row that has already been transferred is narrow, The plate member 32 can be easily inserted into the gap 400. Therefore, the sample transfer apparatus 1 can smoothly transfer the container 300 to the second rack 200 in which the arrangement pitch of the recesses 203 into which the container 300 is inserted is relatively small.
[0118]
At this time, as described in [8] above, since the posture of the container 300 in the adjacent row that has already been transferred is regulated by the regulating means 5, these containers 300, the descending container 300, Contact and interference with the gripping mechanism 3 (plate member 32) can be reliably prevented, the container 300 can be transferred smoothly and carefully, and damage to the container 300 can be reliably prevented. .
[0119]
At this time, the upper end opening of the container 300 that has already been transferred is covered with the cover portion 512 of the regulating member 51. This ensures that even if the sample in the container 300 being transferred jumps, the droplets are not likely to be mixed into the already transferred container 300 and contamination is reliably prevented. Can do.
[0120]
At this time, the control means 15 performs the same control as in [5] above, stops the lower end of the container 300 just before the bottom 202 of the second rack 200, and then grips the container 300 with the gripping mechanism 3. Release it. Since the container 300 transferred this time is shorter than the container 300 transferred in [4], the gripping mechanism 3 is lowered to a lower position than in the case of [4] (FIG. 10). After that, the grip on the container 300 is released. As described above, the sample transfer device 1 controls the operation of the gripping mechanism 3 and the gripping mechanism lifting mechanism 41 based on the detection result of the length detection unit of the container 300 as described above. Thus, even when containers 300 of different lengths are mixed for each first rack 100, the lower end of the container 300 is prevented from colliding with the bottom 202 of the second rack 200 during the transfer, and quietly (carefully) ).
[0121]
[10] Thereafter, the sample transfer apparatus 1 similarly transfers the containers 300 sequentially to the third row, fourth row, and fifth row recesses 203 from the right side of the second rack 200 in the drawing.
[0122]
When the transfer to the second rack 200 is completed, the control means (information creating means) 15 stores the container barcode reader 13 from the barcode label 301 of each container 300 stored in the storage unit 71. The read information and the information read by the second rack barcode reader 14 from the barcode label 201 of the second rack 200 are read out, and each of the information held (stored) in the second rack 200 based on these information. Management data (management information) for specifying each container 300 is created, and the management data is output (transmitted) to the management system 500. Further, the created management data may be stored in the storage unit 71.
[0123]
The management data corresponds to, for example, information identifying the second rack 200 such as a rack ID number, each position where the container 300 of the second rack 200 is held, and the container 300 held at each position. Information for specifying each container 300 is included.
[0124]
Here, an example of information (information creation) for identifying each container 300 by associating each position where the container 300 of the second rack 200 is held with the container 300 held at each position. explain.
[0125]
Each of the 50 recesses 203 of the second rack 200 indicates its position (corresponding to the position), for example, numbers (1 to 50) (recess numbers) are assigned, The container ID number of the container 300 inserted into the recess 203 is associated with the recess number of each recess 203. For example, when the container 300 with the container ID number “a” is inserted into the concave portion 203 with the concave portion position number “1”, data indicating that fact is created, and this is stored in the concave portion numbers “1” to “50”. This is performed for all of the recesses 203 in FIG.
[0126]
In this case, when there is a recess 203 (empty recess 203) in which the container 300 is not inserted in the second rack 200, for example, when the container 300 is not inserted into the recess 203 of the recess number “2” ( When the recess 203 with the recess number “2” is empty), data indicating that is created.
[0127]
Note that the information on the container 300 side associated with the recess number of the recess 203 into which the container 300 is inserted is not limited to the container ID number of the container 300. In addition to the container ID number of the container 300, the information on the container 300 side further includes information carried on the barcode label 301 attached to the container 300 (related to the specimen stored in the container 300 ( One or more of the corresponding) information) may be included.
[0128]
The management data includes, for example, information indicating the number of containers 300 held in the second rack 200, information for specifying the sample transfer device 1 that has transferred the containers 300, and the like. Also good.
[0129]
When the transfer of the container 300 to the second rack 200 is completed, the control unit 15 operates the second rack transport mechanism 12 to transport the second rack 200 to the downstream side, and the second rack discharge unit. 24, the next empty second rack 200 is transported to the stop position 23, and the container 300 is transferred from the first rack 100 to the second rack 200 in the same manner. Data is created and output (transmitted) to the management system 500. The sample transfer device 1 repeats such an operation.
[0130]
In managing each container 300 held in the second rack 200, each bar code label 201 (for example, rack ID number) affixed to the second rack 200 is used by using the management data. For each second rack 200, the containers 300 held in the second rack 200 can be managed in a lump, whereby a large number of containers 300 can be managed easily, reliably and efficiently. .
[0131]
As described above, the sample transfer apparatus of the present invention has been described with respect to the illustrated embodiment. However, the present invention is not limited to this, and each unit constituting the sample transfer apparatus is an arbitrary element that can exhibit the same function. It can be replaced with the configuration of Moreover, arbitrary components may be added.
[0132]
For example, the moving means for moving the gripping mechanism may be one that can move the gripping mechanism in a three-dimensional direction. The moving means for moving the gripping mechanism is configured to move the gripping mechanism only in the longitudinal direction of the container, and the first rack and the second rack are moved in a direction orthogonal to the container arranging direction of the first rack with respect to the gripping mechanism. You may be comprised so that a container may be transferred by moving.
[0133]
Further, in the present invention, the number of containers held by the first rack is not limited to 10 and may be any number as long as it is 2 or more.
[0134]
The second rack is not limited to holding the containers in 10 rows × 5 columns, but may hold the containers in n rows × m columns, where n and m are each an arbitrary integer of 2 or more. it can. In this case, n does not need to match the number of containers held by the first rack, but preferably matches. When n matches the number of containers held by the first rack, transfer can be performed more efficiently and at high speed.
[0135]
Further, the number of containers that can be gripped by the gripping mechanism may not be the same as the number of containers that can be held by the first rack or the number of rows of containers that can be held by the second rack 200. Good, but preferably the same number. As a result, the container can be transferred at a higher speed, and can be transferred by moving the gripping mechanism only in the two-dimensional direction, so that the moving means of the gripping mechanism grips the gripping mechanism. Therefore, the structure of the moving means can be simplified.
[0136]
The length detection means for detecting the length of the container is provided such that the light projecting part and the light receiving part for projecting and receiving light are movable on the container, and the light projecting part and the light receiving part move relative to the stopped container. And you may be comprised so that the length of a container may be detected.
[0137]
Further, the gripping force stabilizing means (pressing force stabilizing means) is not limited to the one using electrical control, and the gripping force of the gripping mechanism is made constant regardless of the outer diameter of the container by a mechanical mechanism. It may be configured as described above.
[0138]
Further, the regulating member of the regulating means is not limited to a plate-like member, and may be a member having a rod-like portion that can come into contact with the outer peripheral surface of the container held by the second rack. Moreover, the upper end opening of the regulated container may not be covered.
[0139]
In addition, the present invention is not limited to the sample transfer device that transfers the container held in the first rack to the second rack, and conversely, the sample transfer that transfers the container held in the second rack to the first rack. It can also be applied to devices. The sample transfer device of the present invention can perform both the transfer from the first rack to the second rack and the transfer from the second rack to the first rack (the two operating states). Can be switched).
[0140]
【The invention's effect】
As described above, according to the present invention, when a container is transferred, the container held in the row adjacent to the row to be transferred in the second rack and the container held by the holding mechanism or the holding mechanism. Can be reliably prevented from contacting and interfering with each other, and the container can be transferred smoothly.
[0141]
Further, when the restricting member of the restricting means is configured to cover the upper end opening of the container whose posture is restricted, the specimen stored in the container being transferred by being held by the holding mechanism may jump. However, it is possible to prevent the splashes from being mixed into other containers held in the second rack, and it is possible to reliably prevent contamination.
[0142]
The gripping mechanism includes at least one pressing member that presses the outer peripheral surface of the container, a flat plate member that sandwiches the container between the pressing member, and a driving unit that moves the pressing member toward and away from the plate member. When the container is transferred, the gripping mechanism more reliably contacts and interferes with the container held in the row adjacent to the row to be transferred in the second rack. Therefore, the container can be transferred more smoothly.
[Brief description of the drawings]
FIG. 1 is a plan view showing an embodiment of a sample transfer apparatus of the present invention.
2 is a perspective view showing a gripping mechanism in the sample transfer device shown in FIG. 1. FIG.
3 is a cross-sectional plan view showing a gripping mechanism in the sample transfer device shown in FIG. 1 (a state before a container is gripped). FIG.
4 is a cross-sectional plan view (a state in the middle of gripping a container) showing a gripping mechanism in the sample transfer device shown in FIG. 1;
5 is a cross-sectional plan view (a state in which a container is gripped) showing a gripping mechanism in the sample transfer apparatus shown in FIG. 1. FIG.
6 is a perspective view showing a guide member and a second rack in the sample transfer device shown in FIG. 1. FIG.
7 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG.
8 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG.
9 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG. 1. FIG.
10 is a cross-sectional side view showing the configuration and operating state of the sample transfer device shown in FIG.
11 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG.
12 is a cross-sectional side view showing a configuration and an operating state of the sample transfer device shown in FIG. 1. FIG.
13 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG.
14 is a cross-sectional side view showing the configuration and operating state of the sample transfer apparatus shown in FIG.
15 is a schematic block diagram of the sample transfer device shown in FIG. 1. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Sample transfer apparatus 11 1st rack conveyance mechanism 12 2nd rack conveyance mechanism 13 Barcode reader 14 for containers 14 Barcode reader 15 for 2nd racks Control means 2 Apparatus main body 21 Stop position 22 Second rack supply part 23 Stop position 24 Second rack discharge part 3 Grip mechanism 30 Pin 31 Press member 311 Recess 32 Plate member 321 Escape part 33 Support member 331 Through hole 34 Coil spring 35 Frame 36 Drive means 361 Feed screw 362 Belt 363 Grip mechanism opening / closing motor 4 Moving means 41 Grip Mechanism lifting mechanism 411 Support column 412 Bracket 42 Grasping mechanism Horizontal movement mechanism 421, 422 Rail 423 Moving beam 5 Restricting means 51 Restricting member 511 Abutting part 512 Covering part 52 Restricting member moving mechanism 6 Reflective sensor 61 Light projecting part 62 Main unit 64 Optical fiber 71 Storage unit 72 Display 73 Operating section 75 Driver 8 Deformation amount detecting means 81 Light emitting element 82 Light receiving sensor 83 Displacement section 100 First rack 101 Recess 200 Second rack 201 Bar code label 202 Bottom 203 Recess 300 Container 301 Bar code label 302 Flange 400 Clearance 500 Management system R ray

Claims (12)

A first rack that holds a plurality of the tubes, and a second container that holds the containers in n rows × m columns (where n and m are integers of 2 or more, respectively). A sample transfer device that transfers between racks,
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism at least in the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container . A tube-like container for storing a sample, a first rack for holding a plurality of the containers arranged in one row, and the containers arranged in n rows × m columns (where n and m are each an integer of 2 or more) A sample transfer device for transferring between the second rack to be held;
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism at least in the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container . A tube-like container for storing a sample, a first rack that holds the n containers (where n is an integer equal to or greater than 2) in one column, and the containers are n rows × m columns (where m is 2). A specimen transfer device for transferring between the second racks arranged and held in the above integer),
A gripping mechanism capable of simultaneously gripping a plurality of the containers;
Moving means for moving the gripping mechanism in a two-dimensional direction including at least the longitudinal direction of the container;
A restricting means for restricting a posture of the container held in a row adjacent to the row to be transferred in the second rack when the container is transferred;
E Bei and control means for controlling the operation of the gripping mechanism and the moving means,
The regulating means includes a regulating member that can abut on the container whose posture is to be regulated, and a moving mechanism that moves the regulating member, and the container whose posture is to be regulated is being transferred. The specimen transfer device is characterized in that its posture is regulated so as to be separated from the container .   The specimen transfer device according to claim 1, wherein the restriction member covers an upper end opening of the container whose posture is restricted.   The gripping mechanism includes at least one pressing member that presses the outer peripheral surface of the container, a flat plate member that sandwiches the container between the pressing member, and the pressing member that approaches the plate member. The specimen transfer apparatus according to claim 1, further comprising a drive unit that separates the specimen.   The sample transfer apparatus according to claim 5, wherein an opening is formed at a position corresponding to the container of the plate member.   The sample transfer apparatus according to claim 5 or 6, further comprising: a pressing force stabilizing unit that maintains a pressing force of the pressing member against the container regardless of an outer diameter of the container gripped by the gripping mechanism. The gripping mechanism has a biasing member that generates a pressing force of the pressing member against the container by its elastic force,
The pressing force stabilizing means has a deformation amount detecting means for detecting that the deformation amount of the biasing member becomes a predetermined amount, and the deformation amount detecting means detects when the gripping mechanism grips the container. 8. The specimen transfer apparatus according to claim 7, wherein the operation of the driving unit is controlled so that the amount of deformation of the biasing member becomes a predetermined amount according to a result.   The specimen transfer apparatus according to claim 8, wherein the deformation amount detecting means optically detects that the deformation amount of the biasing member becomes a predetermined amount. The deformation amount detecting means includes a light projecting unit, a light receiving unit that can receive light emitted from the light projecting unit, and a displacement unit that is displaced according to the deformation amount of the biasing member,
The displacement portion is installed to block light emitted from the light projecting portion when the deformation amount of the biasing member reaches a predetermined amount,
The deformation amount detecting means detects that the deformation amount of the urging member becomes a predetermined amount when the light receiving unit changes from a state of receiving the light emitted from the light projecting unit to a state of not receiving the light. Item 10. The specimen transfer device according to Item 9.   The sample transfer device according to claim 1, further comprising a transport mechanism that transports the first rack.   The sample transfer apparatus according to claim 1, further comprising a transport mechanism that transports the second rack.

Images