DE4307738A1 - Specimen collection mechanism for microtome slicing machine - has conveyor belt with adjustable incremental travel indexed to cutting strokes and manipulator element for specimen handling - Google Patents

Abstract

The specimen collection mechanism has a conveyor belt (41) for depositing the successive sections in a temperature controlled water-bath (4) for subsequent examination. The operator controlled vertical movements of the spring (16) returned sample (S) clamp (K) during slicing by the knife assembly (5,7,8) is translated into a reciprocating motion of the link (25) via the rack (13), pinion (22) and cranks (23,36). A uni-directional coupling on the shaft (34) causes intermittent travel of the conveyor (41) top towards the bath (4) linked to each cutting stroke. A manipulator wire (45,46) assists specimen transfer and their spacing on the conveyor (41) is adjustable via the slot (39). USE/ADVANTAGE - Assists operator handling of fragile specimen sections without resort to time - consuming use of tweezers etc. Deposits sections in bath in controlled order unlike continuously rotating alternative conveyor systems.

Description

The invention relates to a device which in one Microtome is used to collect cut pieces.

In conventional microtomes there is a collection device located near the front of the microtome. The Collection device is continuous over an endless Belt driven regardless of whether the microtome Carries out cutting or not. More specifically said a sample made with paraffin (wax) or artificial resin was preserved, cut into thin slices. After the cutting process is completed, a  cut piece by hand on an endless belt placed the piece in a liquid tub wearing. The collecting device becomes continuous driven while the microtome sliced the sample cuts. If no collection device is used, an operator must carefully cut each Pick up a piece with tweezers without destroying it. The piece is then placed in the water tub and widened by stretching.

The cut pieces do not become continuous placed on the belt and successively into the water Tub promoted. Therefore, there is a problem that the Operator the desired cut pieces cannot select efficiently.

If no collection device is used, there is Problem that the operator has an easy task like picking up the pieces over a long period of time must perform repeatedly. Therefore, it would be desirable the efficiency and working conditions of the To improve operators.

In addition, the operator could thin the Damage sliced pieces (e.g. µm), while cutting the sliced pieces records.

The object of the invention is to solve a problem To create a collecting device that slices the  promotes cut pieces intermittently while doing so collects the pieces quickly and easily.

This object is achieved according to the invention by characterizing features of claim 1 solved. Further Features are contained in the subclaims.

To solve the above problem, the present invention an endless conveyor belt for Promote the sliced pieces and one Drive mechanism for the intermittent drive of the endless conveyor belt.

As a result, according to the invention, the slices cut pieces continuously proximal to each other placed on the conveyor belt and successively through the Conveyor belt conveyed through intermittently the drive means is driven.

The invention is described below with reference to the Drawings based on a preferred embodiment as Example described.

Fig. 1 is a side view of a collection device and a clamping mechanism according to a preferred embodiment of the present invention;

Fig. 2 is a top plan view of the collecting device of Fig. 1;

Fig. 3 is an enlarged rear view of the collecting device of Fig. 1, illustrating its operation;

Fig. 4 is a partial side view of the collection device of Fig. 1, illustrating its operation;

Fig. 5 is a greatly enlarged side view of a wire or the like used in the collecting device of Fig. 1; and

Fig. 6 is an enlarged side view of a connecting rod of a collecting device according to a modified embodiment of the present invention.

First, the collecting device of the invention attached to a rotary type microtome will be described with reference to FIGS. 1 to 5.

As shown in FIGS. 1 and 2, a holder which is fixed to the base 2 is arranged at the front end (not shown) of the microtome body. A partition 3 is in an upright position between two columns 2 b. A first column 2 b is arranged on the right end section of the holder, and a second column 2 b is arranged on the left end section of the holder. These columns are rectangular in cross section. A water pan 4 , which collects the pieces cut by the microtome, is attached to the front end surface of the wall 3 . A heater 54 is disposed within the outer bottom surface of the tub 4 to maintain the water temperature in the tub 4 substantially constant.

As shown in Fig. 1 and 2, each column 2 b is provided in an upper part of it with a notch 2 a, which is inclined towards the rear in cross section, and is horizontally extended. A base plate 5 is held between the columns 2 b. Each distal end of the plate 5 is inserted into the associated notch 2 a. The plate 5 is attached to the front surface of the columns by means of a threaded rod pair 6 . These rods 6 are screwed into the corresponding upper part of the columns 2 b. A connecting groove 5 a is formed in the upper part of the plate 5 . A clamping plate 7 is attached to the plate 5 by a screw 7 b. An engaging projection 7 a, which is formed on the rear end surface of the plate 7 , is received in the groove 5 a. A blade 8 for slice-wise cutting of a sample S is removably clamped between the plates 5 and 7 .

As shown in FIGS. 2 and 3, a guide rail 9, which extends vertically on the rear surface of the right column 2 is attached b. Two guide grooves 9 a extend in the longitudinal direction and are formed in the right and left surfaces of the rail 9 . A guide body 10 , in which a channel is formed, fits on the rail 9 . Two sliding guides 10 a, which protrude and extend in the longitudinal direction, are formed along the two inner sides of the body 10 . Therefore, the body 10 can slide vertically due to the engagement between the grooves 9 a of the rail 9 and the projections 10 a. A movable plate 11 is attached to the rear surface of the body 10 . A pressure arm 12 , which extends rearward, is attached to the upper part of the plate 11 . A vertically extending rack 13 is attached to the right side of the front part of the plate 11 . A lower arm 14 extending in the rearward direction is fixed to the rear surface of the plate 11 .

An upper arm 15 extends in the backward direction and is attached to the rear surface of the column 2 b. Hook holes 14 a and 15 a are formed on the lower and upper arms 14 and 15 . A coil spring 16 is fixed between the arms 14 and 15 and on these in such a way that the ends of the spring 16 are suspended in the holes 14 a and 15 a. In other words, the rack 13 is urged in an upward direction by the force of the spring 16 .

A support arm 17 , which extends in the forward direction, is attached to the front surface of the right column 2 b. A support rod 18 is connected to the distal end portion of the arm 17 via a self-tapping screw or sheet metal screw 19 . An elongated hole 20 , which extends in the longitudinal direction, is formed on the proximal end part of the support rod 18 . The screw 19 is inserted into the slot 20 so that the support rod 18 can be moved to adjust its position within the range of the hole 20 .

As shown in FIGS. 1 and 2, a support shaft 21 protrudes beyond the right side surface of the right column 2 b. A gear 22 is rotatably supported by the shaft 21 and engages in the rack 13 . Therefore, the vertical movement of the rack 13 causes the gear 22 to rotate in opposite directions. A first crank 23 is inserted through the distal end portion of the shaft 21 . The crank 23 is attached to the gear 22 by means of a pair of screws 24 . Therefore, the first crank 23 and the gear 22 can be rotated together. The distal end part of a connecting rod 25 is rotatably connected to the crank 23 via a connecting pin 26 .

Two support bars 27 are inclined slightly upward with respect to the front surface of the wall 3 , and are attached to the front surface of the wall 3 . The bars 27 are spaced a predetermined distance apart. Two holding frames 28 , which are inclined downward with respect to the back-to-front direction, are attached to an associated distal end portion of the rod 27 . The free distal ends of the frames 28 are arranged above the water tub 4 . Two strap tensioners 30 , which are attached to the upper rear part of the frames 28 and extend along the extension line of the frames 28 , are connected to the frames 28 by means of set screws 31 .

The upper end parts of the tensioners 30 are connected to each other by a connecting shaft (not shown). An elongated hole 32 is formed on the lower part of each tensioner 30 . The screw 31 is fitted in the hole 32 and screwed into the frame 28 . The tension of the belt can be adjusted by moving the position of the screw 31 relative to the hole 32 . A driven pulley 33 is rotatably held between the upper parts of the tensioners 30 .

A shaft 34 a is rotatably supported by the distal front end of each frame 28 . The shaft 34 a is connected to a connecting shaft 34 via a one-way clutch 35th The shaft 34 extends beyond the coupling 35 and penetrates the holding rod 18 . Furthermore, the shaft 34 a is used in such a way that it can only be turned counterclockwise by actuating the one-way clutch 35 ( FIG. 1). A second crank 36 is attached to the right distal end portion of the shaft 34 for rotating the shaft 34 . The front end of the rod 25 is rotatably connected to the second crank 36 via an outer threaded portion formed at the front end of the rod 25 and a nut 37 attached to the threaded portion.

An elongated hole 39 is formed on the second crank 36 along the length of the second crank 36 . The position of the rod 25 can be adjusted by changing the position at which the distal end of the rod 25 is inserted into the hole 39 . In other words, the rotational speed of the shaft 34 can be adjusted by changing the engagement position of the rod 25 with respect to the second crank 36 . The distal left part of the shaft 34 is also connected to an actuatable knob 38 for the manual rotation of the shaft 34 .

A drive pulley 40 is attached to the shaft 34 a, which is arranged between the frame 28 to enable them to rotate with the shaft 34 a. A timing belt or belt 41 is used to convey the cut pieces, and is disposed between the drive pulley 40 and the driven pulley 33 . The belt 41 is made of polyurethane (rubber) to prevent the generation of electrostatic charges. In this way, the drive pulley 40 drives the belt 41 to convey the cut pieces to the water pan 4 .

A support rod 42 , which extends in the upward direction, is fixed to the central part of the left frame 28 . A groove 42 a is formed in the upper end of the rod 42 . The proximal end of a support rod 43 is fitted in the groove 42 a, is secured by a support pin 44 and is rotatable about the pin 44 . An anti-curling wire 45 slidably penetrates the holding rod 43 and can be moved together with the holding rod 43 . The wire 45 is U-shaped. A knob 46 is generally T-shaped and attached to the front ends of the wire 45 . The wire 45 prevents the samples S from curling on the belt 41 .

A clamping device used in the microtome is Mechanism K described.

As shown in FIGS. 1 and 3, the sample S is clamped by the base of the clamping mechanism K. A holding projection 47 is fixed to the right side surface of the base of the clamping mechanism K. A rod 48 extends through the holding projection 47 and is vertically displaceable in a predetermined range. A contact flange 49 is also attached to the lower end of the rod 48 to define the movement of the rod 48 . A coil spring 50 for absorbing shocks is arranged around the rod 48 between the flange 49 and the holding part 47 .

Below is the operation of the above Collection device described.

The wire 45 is placed above the belt 41 and the sample S is cut into pieces with thicknesses in the range between 3 and 5 μm by the manually operated microtome. As shown in FIG. 5, the operator winds a first cut piece P around the back portion of the wire 45 . The cut piece P is brought into contact with the strap 42 by pulling and holding the knob 46 so that the wire 45 is slowly pulled forward to stretch the piece P that has wrapped around the wire 45 . If the piece P cannot be removed from the wire 45 while the wire is being pulled forward, a brush is used to remove the cut piece from the wire 45 to thereby place it on the belt 41 . The preparation for conveying the cut piece P can be done by turning over the holding rod 43 and removing the wire 45 from the belt 41 .

When the microtome is started by operating a control switch (not shown), the clamping mechanism K is lowered and the sample S is cut into thin slices by the blade 8 . The cut piece P is then placed on the belt 41 . At the same time, flange 49 abuts arm 12 and rod 48 moves upward against the force of spring 50 . In addition, the arm 12 moves down. In other words, the plate 11 is moved down against the force of the spring 16 , and the rack 13 is also moved down to its lower moving point, whereby the gear 22 is rotated in accordance with the movement of the rack 13 .

As shown in FIG. 4, the first crank 23 rotates synchronously and in the same direction as the gear 22 when the gear 22 rotates clockwise. The rotational movement of the first crank 23 causes the rod 25 to be pulled backwards, and the rotational movement of the second crank 36 causes the shaft 34 , which is integrally connected to it, to rotate in the counterclockwise direction. As the shaft 34 rotates, the drive pulley 40 rotates counterclockwise. As a result, the belt 41 intermittently feeds the cut piece P into the water tub 4 , so that the cut pieces are separated from each other by a predetermined distance. The belt 41 conveys the cut pieces P continuously into the water tub 40 , where they usually float on the water surface.

Subsequently, the clamping mechanism K moves from its lower point of movement to its upper point of movement, and the rod 48 and the arm 12 are caused to move upward. In other words, the plate 11 is moved upward by the force of the spring 16 . The upward movement of the rack 13 causes the gear 22 to rotate in the reverse direction.

As the gear 22 rotates counterclockwise, the first crank 23 rotates in the same direction as the gear 22 . The rotational movement of the crank 23 causes the rod 25 to be pulled forward. Furthermore, the second crank 36 rotates clockwise around the shaft 34 which is integrally connected to the rod 25 . Under these circumstances, the shaft 34 is not rotated via the one-way clutch 35 . In other words, as the clamp mechanism K moves from its lower moving point to its upper moving point, the belt 41 stops feeding the cut pieces P because the shaft 34 does not rotate.

When the placement area or the conveyance distance of the cut piece P needs to be changed, the engagement position of the rod 25 in the hole 39 is changed.

For example, when the placement area of the cut piece P is to be enlarged, the engagement position of the front part of the rod 25 is moved further away from the shaft 34 . On the other hand, when the placement area of the cut piece P is to be reduced, the engagement position is moved closer to the shaft 34 .

The clamping mechanism reciprocates vertically, which means that the cut pieces P are continuously fed into the water tub 4 . The cut pieces P are stretched on the belt 41 by means of the wire 45 and picked up by means of tweezers for placement on a slide (not shown).

Therefore, in the present device, the movement of the belt 41 is temporarily stopped while the microtome is cutting the sample S. In other words, the belt 41 is operated intermittently. As a result, the cut pieces P are placed equidistantly at the predetermined distance on the belt 41 and conveyed into the water tub 4 . Therefore, the operator can efficiently select the cut pieces P out of the water tub.

Since the belt 41 is caused to move a predetermined distance between the upper and lower moving points due to the vertical movement of the clamp mechanism K, the successive pieces on the belt 41 do not overlap. Since the cut pieces P are automatically dropped into the water tub 4 instead of being picked up manually, the cut pieces are at most minimally damaged. In all likelihood, the damage can even be completely prevented. In addition, the operator can now efficiently remove the cut pieces P from the tub.

Before the microtome is actuated, the first cut piece P wraps around the rear part of the wire 45 . The piece P is stretched by pulling the wire forward, and then pushed against the belt 41 . Therefore, none of the cut pieces P is lost. After the cut piece P has been stretched, the wire 45 can be turned over to disengage from the belt. The wire 45 does not interfere with the cutting process.

In addition, if the operator wants to adjust the conveying range of the belt 41 , the adjustment can be made easily by changing the engaging position of the front or rear part of the rod 25 within the hole 39 .

This setting is for housing cut pieces of different sizes necessary. Although only one embodiment of the present Invention has been described, it is for a person skilled in the art obvious that the present invention also in other special shapes can be carried out without the Deviate the idea or scope of the invention.

• (1) For example, in the embodiment described above, the conveyance range of the belt 41 is adjusted by changing the engagement position of the rod 25 within the hole 39 . A further, alternative adjustment can be carried out in the following way: As shown in FIG. 6, the rod 25 contains a first rod part 51 and a second rod part 52 . The rod parts 51 and 52 have corresponding elongated holes 51 a and 52 a. If the elongated holes 51 a and 52 a overlap each other, a bolt 53 is inserted through them and tightened with a corresponding nut (not shown), whereby an axial adjustment of the length of the rod 25 is possible. The rod parts 51 and 52 are displaceable relative to one another. If the operator wishes to adjust the conveying range of the belt 41 , the length of the rod 25 can be shortened or extended appropriately by the length of the rod by axially displacing the rod parts 51 and 52 with respect to each other and by tightening the bolt 53 with the nut 25 to be determined. In order to enlarge the conveying area, the entire length of the rod 25 is shortened. Conversely, the entire length of the rod 25 is increased in order to reduce the conveying area.
• (2) In the embodiment described above, the heated water color pigments can be added to the to dye cut pieces. Furthermore cold Water can be used instead of hot water.

As can be seen from the preferred embodiment described above, the pieces cut off from the microtome can be collected quickly and efficiently in the tub 4 since they are automatically and intermittently conveyed into this.

Claims (5)

1. collecting device for a microtome and for collecting pieces (P) cut therewith, characterized by conveying means ( 41 ) for automatically conveying the cut pieces (P) to a predetermined location ( 4 ), and
Drive means ( 13 , 25 , 34 ) for intermittently driving the conveying means ( 41 ). 2. Collecting device according to claim 1, characterized in that the conveying means ( 41 ) have a variable conveying area. 3. Collection device according to claim 1 or 2, characterized in that
that the microtome contains clamping means (K) for holding a sample (S), and
that the operation of the clamping means (K) is coordinated with that of the conveying means in such a way that the cut pieces (P) are generally placed equidistantly on the conveying means ( 41 ). 4. Collecting device according to one of the preceding claims, characterized in that it contains means ( 45 ) to prevent the curling of the cut pieces (P). 5. Collecting device according to one of the preceding claims, characterized in that the conveying means ( 41 ) contain an endless belt or an endless conveyor belt.