JP2018000445A - Instrument storage stand - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact device storage stand which does not lose operability of each of a plurality of laboratory instruments even when the laboratory instruments are attached in a highly-dense aligned manner in a vertical direction.SOLUTION: An instrument storage stand includes: a support pillar 20; a plurality of support parts 30a-30f of three or more stages which support laboratory instruments 93a-93f aligned on each of the stages in a vertical direction on a front face wall of the support pillar 20; and an angle adjustment mechanism which flexibly adjusts an attachment angle θ between an axis of the support pillar 20 and at least one of the support parts 30a-30f supporting the laboratory instruments 93a-93f on upper side and the support parts 30a-30f supporting the laboratory instruments 93a-93f on lower side while the laboratory instruments 93a-93f are attached to each of the plurality of support parts 30a-30f.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a device storage stand that stores a plurality of physics and chemistry equipments at high density and can operate these physics and chemistry devices without interfering with each other.

  A medical stand that supports a medical device such as an infusion pump or a syringe pump is used for infusion or the like (see Patent Document 1). Conventionally, each device storage stand such as a medical stand has been designed to support and use one medical device per unit. However, in recent medical practice, a plurality of device storage stands are provided in one device storage stand. It is required to use medical devices that are mounted side by side. In that case, the attachment position of the upper medical device interferes with the position of the lower medical device, or the operation unit of the lower medical device is hidden to cause a problem that it is difficult to operate the lower medical device. .

JP 2013-59366 A

  In view of the above problems, the present invention can avoid the interference of the mounting positions of a plurality of physics and chemistry devices adjacent in the vertical direction, even if a plurality of physics and chemistry devices such as medical devices are mounted side by side with high density. An object of the present invention is to provide a compact equipment storage stand that does not impair the operability of the physical and chemical equipment.

  In order to achieve the above object, according to a first aspect of the present invention, there is provided (a) a support column having a front wall and extending in a vertical direction, and (b) a base portion. Is fixed to the front wall, supports the physics and chemistry equipment arranged in each step in the vertical direction along the front wall, and each is rotatable about the rotation axis included in the base part, respectively And (c) an equipment storage stand provided with an angle adjusting mechanism that independently adjusts the angle of attachment of the plurality of support portions to the axial column.

  According to the present invention, even when a plurality of physics and chemistry equipments are mounted side by side in high density, interference between the attachment positions of the plurality of physics and chemistry equipments adjacent in the vertical direction can be avoided, and the operability of each physics and chemistry equipment is impaired. A compact device storage stand can be provided.

It is a front view which illustrates typically the outline of the composition seen from the front side in the state where the physics and chemistry equipment is not carried of the equipment storage stand concerning a 1st embodiment. It is a rear view which illustrates typically the outline of the composition seen from the back side of the equipment storage stand concerning a 1st embodiment. It is a right view which illustrates typically the outline of the structure of the apparatus storage stand which concerns on 1st Embodiment in the state which carried the angle of the support part in the state which is not mounting a physics and chemistry apparatus. It is sectional drawing seen from the AA direction in FIG. FIG. 5 is a cross-sectional view schematically illustrating an outline of a configuration of a support portion of a B portion in FIG. 3 when viewed from a CC direction in FIG. 4. It is a right view which illustrates typically the outline of the structure of the apparatus storage stand which concerns on 1st Embodiment in the state which adjusted the angle so that the support part had an angle in the state which is not mounting physics and chemistry equipment. The equipment storage stand which concerns on 1st Embodiment is a right view which typically illustrates the state which connected the physics and chemistry equipment through the attachment base which does not have an angle to the support part which adjusted the angle so that it may have an angle. is there. The apparatus storage stand according to the first embodiment is schematically enlarged by partially expanding a state in which the physics and chemistry equipment is connected via a mounting base having no angle to the support portion adjusted to have an angle. It is a bird's-eye view (perspective view) demonstrated to 1st. The equipment storage stand which concerns on 1st Embodiment is a right view which typically illustrates the state which connected the physics and chemistry equipment through the attachment base which has an angle to the support part which adjusted the angle so that it may not have an angle. is there. It is a circuit diagram explaining typically connection of an outlet and an external power supply which a pillar of a device storage stand concerning a 1st embodiment incorporates. It is a front view which illustrates typically an outline in the state where the physics and chemistry equipment is not carried of the composition of the equipment storage stand concerning a 2nd embodiment. It is a right view which illustrates typically the outline of the structure of the apparatus storage stand which concerns on 2nd Embodiment in the state which set the angle of the support part to 0 degrees in the state which is not mounting physicochemical equipment. It is sectional drawing seen from the DD direction in FIG. It is sectional drawing seen from the EE direction in FIG. It is sectional drawing seen from the FF direction in FIG. The equipment storage stand which concerns on 2nd Embodiment is a right view which typically illustrates the state which connected the physics and chemistry equipment through the attachment base which does not have an angle to the support part which adjusted the angle so that it may have an angle. is there.

  Next, first and second embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic, and the relationship between the thickness and the planar dimensions, the ratio of the thickness of each layer, and the like are different from the actual ones. Therefore, specific thicknesses and dimensions should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

  Also, the following first and second embodiments of the present invention exemplify apparatuses and methods for embodying the technical idea of the present invention, and the technical idea of the present invention is configured as follows. The material, shape, structure, arrangement, etc. of the parts are not specified as follows. The technical idea of the present invention can be variously modified within the technical scope defined by the claims described in the claims.

<First Embodiment>
As shown in FIG. 1, the device storage stand according to the first embodiment of the present invention is provided on the leg base 10 and the leg base 10, and has a width of about 15 cm to 20 cm and a height of 120 cm to 130 cm, for example. A column 20 having a rectangular front wall with a thickness of about 2 mm to 5 mm and extending in the vertical direction is provided. An upper support plate 56 that appears in a boat shape (bathtub shape) when the paper surface of FIG. The upper support plate 56 is formed by bending both ends so that the region connected to the left and right sides of the boat shape appears horizontally, and the first support portion 60a and the second support portion 60b are both cylindrical on the horizontal surfaces of both ends. Is provided.

  The first support part 60a and the second support part 60b can be made of, for example, iron, stainless steel, reinforced plastic, or the like. FIG. 1 is an overall view showing a no-load state in which no physics and chemistry equipment is mounted. Specific examples of “physics and chemistry equipment” attached to the first support portion 60a and the second support portion 60b include, for example, an infusion pump and a syringe. Portable medical devices such as pumps are suitable, but are not limited to medical devices, and may include various electronic devices, scientific devices, small industrial devices, and the like.

  Further, as shown in FIG. 1, on the front wall of the support column 20, below the upper support plate 56, rod-shaped third support portions 30a to 30d arranged on the same straight line at equal intervals in the vertical direction. 8 support portions 30f are provided. Each of the third support portion 30a to the eighth support portion 30f is a support portion that supports the physics and chemistry equipment on each stage with the respective operation portions and display portions facing upward, and securely fixes them. In the device storage stand according to the first embodiment illustrated in FIG. 1, the six support portions of the third support portion 30 a to the eighth support portion 30 f are illustrated, but the device support stand is not limited to six steps. The number of steps of the support portion can be arbitrarily selected as long as it is three or more. The number of steps of the support portion may be determined in consideration of the size of the physics and chemistry equipment and the height of the door when moving the equipment storage stand. The size of the third support portion 30a to the eighth support portion 30f can be configured as, for example, a round bar having a diameter of about 2.5 cm to 3 cm and a length of about 4.5 cm to 5 cm, but is not limited to these dimensions and shapes, What is necessary is just to determine suitably considering the magnitude | size and shape of the physics and chemistry equipment to support. In the medical field, the number of steps of the support portion of the device storage stand may be determined in consideration of the usage environment such as the number of beds in the room to be used.

  The front wall of the support column 20 does not necessarily have to be a flat plane, and may have a stepped portion in part or an arcuate surface. Furthermore, the device storage stand according to the first embodiment is configured so that the third support portion 30a to the eighth support portion 30f are attached to the third support portion 30a to the eighth support portion 30f, respectively. An angle adjustment mechanism is provided that can adjust the attachment angle θ of the eighth support portion 30f to the support column 20 independently of each other. When the device storage stand according to the first embodiment is a medical stand, a pole 70 is provided on the support column 20 so as to extend upward, and an infusion bag is provided at the upper end of the pole 70. Hanger 80 for suspending etc. may be provided.

  As shown in FIG. 4, the leg base 10 has a rectangular parallelepiped main body 11 arranged in the center in a plane pattern, and one end of each of the leg bases 10 extending outward from the side surface on the long side of the main body 11. The other end includes four leg members 12 a to 12 d attached to the main body 11. The main body 11 and the leg members 12a to 12d of the leg base 10 are all made of iron, stainless steel, reinforced plastic, or the like as a main material and have a certain strength. The load resistance of the leg base 10 can be set to about 65 kg, for example.

  One end of each of the four leg members 12a to 12d is arranged in a planar pattern so as to be positioned at four corners of a rectangle larger than the rectangle of the main body 11 of the leg base 10, and the leg base 10 is generally H-shaped or It approximates an X shape. A total of four casters 40a to 40d are rotatably provided below one end of each of the four leg members 12a to 12d, corresponding to each leg member 12a to 12d.

  As shown in FIG. 3, the diameter R of the casters 40a to 40d is preferably a large diameter of about 95 mm, for example. Since the casters 40a to 40d have a large diameter, it is possible to prevent the casters 40a to 40d from being caught in grooves and steps, and to prevent the device storage stand from falling.

  Further, in the region on the right side of the leg base 10 shown on the lower side in FIG. 3, the attachment shafts of the leg base 10 and the casters 40a to 40d are illustrated by broken lines. On the other hand, on the right side of the broken line, an alternate long and short dash line passing through the center of the circle of the casters 40a to 40d and parallel to the broken line is illustrated.

  The load applied from above by making the distance d between the broken line and the alternate long and short dash line the smallest, that is, by bringing the casters 40a to 40d and the mounting position of the leg base 10 and the centers of the casters 40a to 40d as close as possible. Is applied to a position close to the rotation center of the casters 40a to 40d, so that the casters 40a to 40d can be easily rotated even when a load is applied.

  In the equipment storage stand according to the first embodiment, the leg base 10 forms a caster base. In this specification, the left side where the support portion provided in the column 20 in the state in FIG. 4 is defined as “front”, and the right side opposite to the support portion is defined as “back”. “Back” is merely a selection for convenience and does not limit the invention.

As shown in FIG. 3, the width of the leg base 10 in the front-rear direction forms the maximum width W ₂ of the leg base 10. The maximum width W ₂ of the leg base 10 is longer than the maximum width W ₁ of the hanger 80. Therefore, the equipment storage stand according to the first embodiment has a quadrangular pyramid shape (pyramid shape) that expands from the upper side to the lower side if a rough outer shape is defined so as to surround the whole with a plurality of planes. Is arranged at a height position of about ¼ from the bottom of the total height.

  In FIG. 4, of the four leg members 12a to 12d, the two leg members 12a and 12b to which the two casters 40a and 40b on the front side are attached are the two casters 40c on the back side. It is longer than the two leg members 12c and 12d to which 40d is attached. That is, the main body 11 of the leg base 10 is unevenly distributed on the back side corresponding to the right side in FIG. 4 rather than the center of the rectangle whose contour is estimated by the other end of each of the four leg members 12a to 12d in a planar pattern. Has been placed.

  As shown in FIG. 1, the column 20 is provided on the upper surface of the main body 11 of the leg base 10 so as to be perpendicular to the upper surface. As shown in FIG. 4, the support column 20 is provided substantially at the center of the main body 11 of the leg base 10 that is unevenly distributed in the back side direction. As shown in FIG. 4, the support column 20 has a rectangular tube shape having a box shape with a rectangular cross section. The long side of the rectangle shown by hatching in the cross section of FIG. 4 can be set to about 150 mm, for example, and the length of the short side can be set to about 80 mm. The column 20 is mainly made of iron, stainless steel, reinforced plastic, or the like. Can be manufactured.

  The column 20 and the leg base 10 are screwed at four points using the rectangular four corner regions of the column 20. Therefore, the unity of the support column 20 and the leg base 10 is enhanced so that it is difficult to come off even when used for a long time. The third support portion 30a to the eighth support portion 30f can be made of, for example, iron, stainless steel, reinforced plastic, or the like, similarly to the first support portion 60a and the second support portion 60b. As the physicochemical device attached to the third support portion 30a to the eighth support portion 30f, a portable medical device is suitable as in the case of the physicochemical device attached to the first support portion 60a and the second support portion 60b. However, it is noted that the physicochemical devices attached to the third support portion 30a to the eighth support portion 30f are not limited to medical devices, and may include other portable physicochemical devices such as various electronic devices. I want. The third support portion 30a to the eighth support portion 30f correspond to “support portions” to which the angle adjustment mechanism of the present invention is coupled.

  As shown in the rear view of FIG. 2 and the right side view of FIG. 3, a handle for pushing and pulling the device storage stand is provided at the height of the vertical center on the back wall of the column 20. 51 is provided. The back wall of the support column 20 does not necessarily have to be a flat plane, and may have a stepped portion or a circular arc surface. A hook 55 for hooking various cords and the like is provided on the back wall of the support column 20 between the handle 51 and the leg base 10. An external connection terminal 21 is provided under the hook 55 on the back wall of the column 20. As shown in FIG. 3, a power switch 27 for turning on and off the device storage stand is provided on the upper portion of the right side wall of the column 20.

  As shown in FIG. 2, the first outlet 26 a and the second outlet 26 b are provided at the same height in the left-right direction on the upper part of the back wall of the column 20. The first outlet 26a is connected to a physicochemical device supported by the first support portion 60a via a dedicated power cord, and the second outlet 26b is a physicochemical device supported by the second support portion 60b. Connected via power cord. Each of the first outlet 26 a and the second outlet 26 b has a main body structure that is built inside the rectangular tube of the column 20 and is electrically connected to the external connection terminal 21 inside the column 20.

  As shown in FIG. 3, below the power switch 27 on the right side wall of the column 20, there are provided a third outlet 23a to an eighth outlet 23f provided on the same straight line at equal intervals in the vertical direction. Yes. Each of the third outlet 23a to the eighth outlet 23f has a one-to-one correspondence with each of the third support portion 30a to the eighth support portion 30f, and is provided at substantially the same height as the corresponding support portion. . Similarly to the first outlet 26 a and the second outlet 26 b, the portions constituting the respective main body structures are disposed inside the square tube of the column 20 and are electrically connected to the external connection terminal 21 inside the column 20.

  Next, the angle adjustment mechanism of the third support portion 30a to the eighth support portion 30f of the device storage stand according to the first embodiment will be specifically described by paying attention to the fourth support portion 30b. As shown in FIG. 5, the angle adjusting mechanism of the fourth support portion 30 b has one end (upper end) connected to the lower end of the rod-like fourth support portion 30 b and the other end of the base portion 34 ( The lower end is provided with a rod-like rotary shaft 32 that is provided horizontally so as to be orthogonal to the axial direction of the base portion 34, and a base portion 31 that supports both ends of the rotary shaft 32. The base portion 31 is fixed to the front wall of the column 20.

  The base portion 31 has a recess having an upper opening, and a rotating shaft 32 is provided inside the recess. The rotating shaft 3 is provided inside the concave portion formed by the base portion 31 so as to bridge between opposing side walls constituting the concave portion. The base portions 34 are combined with each other so as to be rotatable with respect to the rotation shaft 32. That is, the fourth support portion 30 b is attached to the support column 20 at the position of the rotation shaft 32, and can freely rotate in the vertical direction along an arc centered on the rotation shaft 32 together with the base portion 34.

  At the other end of the base portion 34, a rotating drum 33 that is fixed to the base portion 34 and rotates together with the base portion 34 is provided. The rotating drum 33 has a cylindrical shape and is arranged concentrically with the rotating shaft 32. Six angle adjustment plates 36b1, 36b2,... 36b6 are provided at equal intervals in the lower region of the peripheral surface of the rotary drum 33. As shown in FIG. 5, the six angle adjusting plates 36b1, 36b2,... 36b6 are provided so as to extend radially outward from the center of the circle on the bottom surface of the rotary drum 33 as seen from the direction in which the thickness appears. .

  The six angle adjusting plates have adjacent angle adjusting plates 36b1, 36b2,... 36b6 when a line connecting the center of the circle of the rotary drum 33 and the plates of the respective angle adjusting plates 36b1, 36b2,. Between the lines of the plates, they are arranged on the peripheral surface where an angle of about 10 ° is formed. That is, a latch function is realized in which the rotation angle when the rotation shaft 32 moves between adjacent angle adjusting plates 36b1, 36b2,.

  On the other hand, a lower through hole is provided in the lower part of the base part 31, and a sliding member 38 serving as an adjustment button for adjusting the mounting angle is freely movable in the vertical direction in the through hole. It is inserted so that it can slide. The upper portion of the sliding member 38 is located inside the concave portion formed by the base portion 31, and is connected to one end of a belt-like crankshaft 35 shown by hidden lines in FIG. The sliding member 38 swings in the vertical direction by the seesaw motion of the crankshaft 35. The crankshaft 35 performs a “first type lever movement (seesaw movement)” with the vicinity of the center as a fulcrum. A fulcrum located at the center in the longitudinal direction of the crankshaft 35 is attached to the base portion 31 so that the crankshaft 35 can freely perform a seesaw motion.

  The other end via the fulcrum of the crankshaft 35 is connected to the lower part of the driven member 37 arranged side by side on the front side of the sliding member 38. In FIG. 5, a fulcrum of the first kind lever movement is shown at a position between the driven member 37 and the sliding member 38. The driven member 37 is pin-coupled to the other end of the crankshaft 35 so as to be able to swing in the vertical direction by the crank mechanism. On the upper surface of the driven member 37, a stopper plate 39 extending toward the rotary drum 33 inside the recess is provided.

  As shown in FIG. 5, the tip of the stopper plate 39 on the rotating drum 33 side and the tip of the angle adjusting plates 36b1, 36b2,... 36b6 extending from the rotating drum 33 to the sliding member 38 share a certain area. The lengths of the stopper plate 39 and the angle adjusting plates 36b1, 36b2,... 36b6 are set so as to contact each other. When the stopper plate 39 and the angle adjusting plates 36b1, 36b2,... 36b6 are in contact with each other, the rotation of the rotary drum 33 is stopped.

  Although not shown in the drawings, the sliding member 38 is attached with mechanical energy supply means such as a spring for supplying a certain elastic force toward the lower side. When elastic energy is supplied and the sliding member 38 is displaced downward, the lower end protrudes from the through hole of the base 31 toward the lower side of the base 31. The driven member 37 is greatly displaced upward through the seesaw motion by the shaft 35. The tip of the stopper plate 39 is designed to come into contact with any one of the six angle adjusting plates 36b1, 36b2,... 36b6 and prevent the rotational movement of the rotating shaft 32 and the rotating drum 33 downward.

  On the other hand, when the sliding member 38 forming the button is pushed into the recess from the lower side, the driven member 37 is displaced downward via the seesaw motion of the crankshaft 35, and the stopper plate 39 is separated from the angle adjusting plate and rotated. The shaft 32 and the rotating drum 33 can freely rotate.

  The rotation angle of the fourth support portion 30b is defined by the angle adjustment plates 36b1, 36b2,... 36b6 with which the stopper plate 39 is in contact when the rotation is blocked. For example, the rightmost angle adjustment plate 36b1 of the stopper plate 39 in FIG. 5 is disposed so as to extend in parallel with the axis of the fourth support portion 30b. Therefore, in the state where the stopper plate 39 is in contact with the rightmost angle adjustment plate 36b1, the rotation angle of the fourth support portion 30b is 0 °.

  Further, the six angle adjustment plates 36b1, 36b2,... 36b6 are arranged so as to make a rotation angle of 10 °, so that the stopper plate 39 is in contact with the second angle adjustment plate 36b2 from the right. The rotation angle of the fourth support portion 30b is 10 °. Thus, the arrangement of the six angle adjusting plates 36b1, 36b2,... 36b6 forms a rotation angle range of about 50 °, so that the fourth support portion 30b is within the range of 0 ° to 50 °. Rotate to move.

  As mentioned above, although it demonstrated as a representative example paying attention to the angle adjustment mechanism of the 4th support part 30b, it is the same also about the other 3rd support part 30a and the 5th support part 30c-8th support part 30f. When the mounting angle θ in the axial direction of the third support portion 30a to the eighth support portion 30f exceeds 50 °, the possibility of interference between the physics and chemistry equipment in the vertical direction increases, and the attachment interval (clearance) of the physics and chemistry equipment separately. A means such as increasing the size is required. If the mounting interval of the physics and chemistry equipment becomes too large, the height of the entire physics and chemistry equipment stand will increase, leading to an increase in the dimensions of the leg base 10 and an increase in the mounting position of the chemistry and chemistry equipment, and workability and operability. Is damaged.

  If the mounting angle θ exceeds 50 °, the position of the display unit and operation unit and the in-plane direction (direction parallel to the surface) of the physics and chemistry device will be on the lower side when considering the direction of the line of sight of the user The possibility of becoming too large increases, and workability and operability are impaired. The attachment angle θ is preferably in the range of 0 ° or more and 50 ° or less, particularly 50 °, because the overall height of the device storage stand can be suppressed and the display unit and the operation unit can be easily arranged.

  The rotation angle of the third support portion 30a to the eighth support portion 30f is maintained at a constant value by the rotary drum 33, the six angle adjustment plates 36b1, 36b2,... 36b6, the sliding member 38 and the stopper plate 39. An angle maintaining device is configured.

  Although not shown, the third support portion 30a to the eighth support portion 30f have a moving speed that reduces the moving speed of the third support portion 30a to the eighth support portion 30f downward when the latch is removed. A mitigation device is further provided. The moving speed relaxation device can be realized, for example, by providing a torque hinge mechanism in combination with the rotating shaft 32 or the rotating drum 33.

  For example, even if the physics and chemistry equipment is attached to the third support portion 30a to the eighth support portion 30f and the maintenance of the attachment angle θ is released by the movement speed relaxation device, Thus, an upward torque is applied so as to resist the downward movement of the third support portion 30a to the eighth support portion 30f. For this reason, the axial mounting angle θ of the third support portion 30a to the eighth support portion 30f is rapidly changed, and the physics and chemistry equipment is detached from the third support portion 30a to the eighth support portion 30f, or the angle adjustment mechanism is damaged. Can be prevented. The shapes of the third support portion 30a to the eighth support portion 30f are not limited to a rod shape, and may be other shapes such as a plate shape or a block shape. In the case of the third support portion 30a to the eighth support portion 30f having other shapes such as a plate shape or a block shape, the direction in which the angle θ changes with respect to the vertical line by the angle adjustment mechanism is the third support portion 30a to the eighth support portion. It is defined as “axial direction” of 30f.

(How to use the angle maintenance device)
Again, the angle adjustment mechanism of the fourth support portion 30b will be mainly described. For example, the user releases the maintenance of the rotation angle by pressing the sliding member 38 with the finger of one hand, and the other The 4th support part 30b is rotated by hand, and it adjusts so that a desired rotation angle may be made. If the finger of one hand is released from the sliding member 38 while maintaining the adjusted rotation angle, the adjusted rotation angle can be maintained even if the other hand is released from the fourth support portion 30b. The same applies to the other third support portion 30a, the fifth support portion 30c, and the eighth support portion 30.

  FIG. 6 illustrates a state where the attachment angles θ of the third support portion 30a to the eighth support portion 30f with respect to the vertical line in the axial direction are all adjusted to 50 ° and maintained. At this time, the distance D between the fourth support portion 30b and the fourth outlet can be set to about 180 mm, for example.

  In FIG. 7, the third support portion 30a to the eighth support portion 30f when the mounting angle θ is adjusted to 50 ° are accommodated through the dedicated third mounting base 91a to the eighth mounting base 91f, respectively. The state where the third physics and chemistry equipment 93a to the eighth physics and chemistry equipment 93f are attached is illustrated.

  The third physics and chemistry equipment 93a to the eighth chemistry and chemistry equipment 93f are connected to the corresponding third and eighth outlets 23a to 23f by dedicated third power cords 95a to 95f, respectively. The total length of the third power cord 95a to the eighth power cord 95f is preferably about twice the distance D between the third support portion 30a to the eighth support portion 30f and the third outlet 23a to the eighth outlet 23f. In the case of the example illustrated in FIG. 7, if the total length is set to about 360 mm, the length required for the movement of the third physics and chemistry equipment 93a to the eighth physics and chemistry equipment 93f can be secured as short as possible to improve the handleability.

  The second physics and chemistry equipment 103b is also connected to the corresponding second outlet 26b by a dedicated second power cord 105b. As shown in FIG. 7, when the third physics and chemistry equipment 93 a to eighth physics and chemistry equipment 93 f are attached to the third support portion 30 a to the eighth support portion 30 f, they are inside the leg base 10 when viewed from the side. The column 20 of the device storage stand according to the first embodiment is attached so as to be unevenly distributed in the rear side direction of the leg base 10.

  In other words, among the four leg members 12a to 12d of the leg base 10, the lengths of the two leg members 12a and 12b on the front side where the third physics and chemistry equipment 93a to 93f are suspended are expressed as follows: It is longer than the two leg members 12c and 12d on the back side. And the position where the support | pillar 20 on a plane pattern is attached to the leg base 10 is unevenly distributed toward the side (back side) opposite to the side from which the 3rd physics-equipment 93a-8th physics-equipment 93f is suspended by the support | pillar 20. Further, the support 20 is provided on the leg base 10.

  The third attachment base 91a to the eighth attachment base 91f will be described with reference to the fourth attachment base 91b illustrated in FIG. The fourth attachment base 91b is a block-like member attached to the back surface of the fourth physics and chemistry instrument 93b on the column 20 side. The fourth mounting base 91b is provided with a U-shaped fixing frame portion 96b that functions as a vise (vise) fixing block in a state where the bottom of the U-shape is fixed to the upper surface of the fourth mounting base 91b. . The fixed frame portion 96b and the fourth attachment base 91b may be configured integrally. The pair of side wall portions of the fixed frame portion 96b extends substantially parallel to the main surface of the fourth mounting base 91b.

  A through hole is provided in one of the pair of side walls constituting the U-shape of the fixed frame portion 96b, and a tightening screw 98b is inserted into the through hole. For example, a female screw is formed on the inner peripheral surface of the through hole, and a male screw corresponding to the female screw of the through hole is formed on the outer peripheral surface of the tightening screw 98b. At one end of the fastening screw 98b located inside the U-shape of the fixed frame portion 96b, a moving block 97b is provided, the main surface of which is arranged so as to be orthogonal to the longitudinal direction of the fastening screw 98b.

  An adjustment knob 99b for rotating the fastening screw 98b is provided at the other end of the fastening screw 98b located outside the U-shape of the fixed frame portion 96b. When the adjustment knob 99b is rotated in the direction in which the tightening screw 98b is fed into the U-shape, the moving block 97b having a holding surface with a V-shaped groove cut is formed in the U-shaped through hole of the fixed frame portion 96b. Proximity toward the opposite side wall.

  As shown in FIG. 8, the fourth support device 30b is firmly clamped between the side wall portion and the holding surface of the moving block 97b on the inner side of the U shape of the fixed frame portion 96b. Is attached to the fourth support portion 30b. At this time, as shown in FIGS. 7 and 8, the in-plane direction of the surface of the operation unit and the display unit of the fourth physics and chemistry instrument 93 b is between the axis of the support column 20 and the axial direction of the fourth support unit 30 b. It is fixed by forming an angle added by about 90 ° to the mounting angle θ to the column 20, and when viewed from the direction of the user's line of sight, the surface of the operation unit and the display unit becomes easy to see, and the fourth physics and chemistry equipment 93b Operability and visibility are improved.

  7 and 8, the shape of the fourth mounting base 91b has a corner portion close to a right angle in which the mounting surface on the side where the fourth physics and chemistry equipment 93b is mounted and the vice surface on the side where the fixing frame portion 96b is mounted are substantially orthogonal to each other. The case is illustrated. However, the shape of the fourth mounting base 91b is not limited to the shape illustrated in FIG. 7 and FIG. 8, and is between the mounting surface on the side where the physics and chemistry equipment is mounted and the vice surface on the side where the fixed frame portion 96b is mounted. The angle may be smaller or larger than 90 °. The angle between the mounting surface of the fourth mounting base 91b and the vise surface is within the range in which the fourth physical and chemical device 93b can be set in the in-plane direction in which the surface of the operation unit and the display unit of the fourth physical and chemical device 93b is easy to see. Can be set arbitrarily. And since the angle adjustment mechanism of the apparatus storage stand which concerns on 1st Embodiment which was illustrated in FIG. 5 can be used, the freedom degree which sets the angle of the operation part of the 4th physics and chemistry apparatus 93b and the surface of a display part Is very expensive.

  In FIG. 9, the structure illustrated in FIG. 7 and FIG. 8 when the angle between the attachment surface on the side where the physics and chemistry equipment is attached and the vice surface on the side where the fixed frame portion 96b is attached is about 20 °. The structures of different third mounting bases 92a to 92f that are different from each other are illustrated. In the new structure illustrated in FIG. 9, the attachment angles θ of the third support portion 30a to the eighth support portion 30f are all 0 °.

  The in-plane directions of the surfaces of the operation unit and the display unit of the third physics and chemistry equipment 93a to 93f are fixed at an angle of about 20 ° with the axis of the support column 20, and the user's line of sight When viewed from the direction, the operability and visibility are improved. As described above, according to the device storage stand according to the first embodiment, it is possible to cope with a case where a physics and chemistry device including the attachment bases 92a to 92f provided with a predetermined angle is attached in advance. High nature.

  As shown in FIG. 10, between the first outlet 26a, the second outlet 26b, the third outlet 23a to the eighth outlet 23f, and the outlet 120 of the external power source, the first physics and chemistry equipment to the eighth physics and chemistry equipment (93a to 93f, 103b) is provided in an electrically connected circuit protector 110.

  As the circuit protector 110, for example, one having a rated capacity of about 5A can be adopted. The external power source is, for example, a commercial AC power source (AC 100 V 50 Hz / 60 Hz). The circuit protector 110 operates when the first physics and chemistry equipment to the eighth physics and chemistry equipment (93a to 93f, 103b) cause a fault such as leakage, and cuts off the power from the external power source.

  The first outlet 26a, the second outlet 26b, and the third outlet 23a to the eighth outlet 23f are all connected at one point on the positive line and the negative line, and the connected lines are connected to the circuit protector 110, respectively. Has been. The connected positive-side line and negative-side line are both connected to the external connection terminal 21. A dedicated power cable 130 of the device storage stand connects between the external connection terminal 21 and the external power outlet 120.

  According to the device storage stand according to the first embodiment, the angle adjusting mechanism for adjusting the mounting angle θ of the third physics and chemistry device 93a to the eighth physics and chemistry device 93f can be mounted at an angle at which the operation unit of each physics and chemistry device can be easily seen. Therefore, operations such as setting the flow rate value of the fluid used for the drip treatment are easy. Moreover, since the display part of each physics and chemistry instrument can be attached at an easy-to-view angle, it is easy to check the set value. Therefore, even if multiple physics and chemistry instruments are mounted side by side with high density, they can avoid interference with the mounting positions of multiple physics and chemistry instruments adjacent in the vertical direction, and do not impair the operability of each physics and chemistry instrument. Equipment storage stand can be provided. In particular, since the attachment angle θ of the third support portion 30a to the eighth support portion 30f with respect to the axial column 20 can be adjusted independently of each other, the sizes of a plurality of physics and chemistry instruments of three or more stages are different from each other. Even in this case, it is possible to cope by adjusting the respective angles of the support portions. As a result, a larger number of physics and chemistry instruments can be safely and securely attached to one instrument storage stand with high density, and space saving at medical sites and the like is possible.

  In addition, according to the angle adjustment mechanism of the device storage stand according to the first embodiment, the attachment angle θ can be adjusted in increments of 10 °. Therefore, the adjustment work is easy and the size of the adjusted attachment angle θ can be set. Easy to grasp. Moreover, since the adjusted attachment angle θ can be maintained at a constant value, there is no stagnation in medical work such as infusion. In addition, since each member constituting the angle adjustment mechanism of the device storage stand according to the first embodiment has a simple structure and can be realized using existing inexpensive parts distributed in the market, the device storage Costs for procuring parts necessary for stand manufacture can be reduced.

  In addition, according to the device storage stand according to the first embodiment, for example, a maximum of eight physics and chemistry devices (six syringe pumps and two infusions) can be taken from one external power outlet 120 provided on a wall or the like. Pumps, etc.).

  In addition, according to the device storage stand according to the first embodiment, the circuit protector 110 is used, and the first physics and chemistry devices to the eighth physics and chemistry devices (93a to 93f, 103b) cause a failure such as electric leakage. However, it is possible to protect the outlet 120 and other physics and chemistry equipment that is not out of order from electric leakage.

  Further, according to the device storage stand according to the first embodiment, it is only necessary to use one dedicated power cable 130 when connecting between the external connection terminal 21 and the outlet 120 of the external power source. Occurrence of hindrance to movement of the device storage stand can be prevented.

  In addition, since dedicated outlets and power cords are provided for each of the first physics and chemistry equipment to the eighth physics and chemistry equipment (93a to 93f, 103b), tangling of cords, scattering on the floor surface, etc. are suppressed, and a fall is caused. To prevent and increase safety. In addition, it is not necessary to prepare eight cords and eight insertion ports between the device storage stand and the outlet 120 of the external power source, so that a state such as a so-called saddle wiring can be avoided.

  Moreover, according to the apparatus storage stand which concerns on 1st Embodiment, since the four leg members 12a-12d are provided so that it may protrude outside the main body 11 of the leg part base 10, stability of an apparatus storage stand Has been increased.

  Moreover, according to the apparatus storage stand which concerns on 1st Embodiment, the low center-of-gravity design which arrange | positions low so that a gravity center may be brought close to the leg base 10 side by being comprised so that the whole may make a quadrangular pyramid shape. It has been made to improve stability during use so that it does not fall over even if a plurality of physics and chemistry instruments are attached and the position of the center of gravity changes.

  Moreover, according to the apparatus storage stand which concerns on 1st Embodiment, the attachment position of the support | pillar 20 is unevenly distributed in the opposite side to the side by which the 3rd physics and chemistry equipment 93a-8f suspends in the front wall of the support | pillar 20. In addition, by designing the attachment position of the column 20 of the leg base 10, even if the center of gravity changes to the outside due to the suspension of the third physics and chemistry equipment 93a to 93f, the entire equipment storage stand There is no loss of balance.

<Modification of First Embodiment>
The external connection terminal 21 is not provided, and the negative line is connected directly from the external power outlet 120 to the first outlet 26a, and the positive line is connected to the first outlet 26a via the circuit protector 110. A circuit configuration may be used. In the case of the equipment storage stand according to the modification of the first embodiment, the positive and negative electrodes are respectively supplied from the first outlet 26a to the second outlet 26b by the crossover wiring, and the third outlet 26c is crossed from the second outlet 26b. A positive electrode and a negative electrode are respectively supplied by wiring. Further, like the negative line, the ground line is directly connected from the external power outlet 120 to the first outlet 26a, and the second outlet 26b is connected to the ground line from the first outlet 26a by a crossover wiring. 26c may be a circuit wiring in which a ground line is connected from the second outlet 26b by a crossover wiring. Even with such a circuit configuration, it is possible to protect against electric leakage and the like, and the device storage stand according to the modification of the first embodiment also has the same effect as the device storage stand according to the first embodiment described above. Can play.

<Second Embodiment>
As shown in FIG. 11, the equipment storage stand according to the second embodiment of the present invention is provided with a leg base 10a, a support column 20 provided on the leg base 10a, and an upper part of the support column 20. 1st support part 60a and 2nd support part 60b, The 3rd support part 30a-8th support part 30f which support the physics and chemistry equipment arranged in the up-down direction on the front wall of the support | pillar 20 are provided. Similar to the device storage stand according to the first embodiment, the front wall of the support column 20 is not necessarily a flat plane, and is partially stepped within a range that does not hinder the construction of a slide mechanism described later. It does not preclude the inclusion of a structure with a cylindrical shape or a cylindrical aspect.

  Moreover, as shown in FIG. 12, the apparatus storage stand according to the second embodiment is in a state in which the third physics and chemistry equipment 93a to 93f are attached to the third support part 30a to the eighth support part 30f, respectively. And an angle adjusting mechanism that freely adjusts the mounting angle θ of at least one of the support part that supports and fixes the upper physics and chemistry equipment or the support part that supports and fixes the lower physics and chemistry equipment. .

  In addition, the device storage stand according to the second embodiment includes a slide mechanism that moves each of the third support portion 30a to the eighth support portion 30f so as to adjust the position in the vertical direction along the front wall side of the support column 20. In addition. The device storage stand according to the second embodiment is provided with the shape of the leg base 10a and the slide mechanism of the third support portion 30a to the eighth support portion 30f in that the device storage stand according to the first embodiment. And different.

  Except for the structure of the leg base 10a and the slide mechanism of the third support part 30a to the eighth support part 30f, the structure is equivalent to the member of the same name in the device storage stand according to the first embodiment, and therefore redundant description will be given. Is omitted.

  As shown in FIG. 13, the leg base 10a has a rectangular parallelepiped main body 11a arranged in the center in a plane pattern, and one end of each of the leg bases 10a projecting outward from the side surface on the long side of the main body 11a. The other end is provided with four leg members 13a to 13d attached to the main body 11a. One end of each of the four leg members 13a to 13d is arranged in a plane pattern so as to be positioned at four corners of a square larger than the rectangle of the main body 11a of the leg base 10a, and the leg base 10a has an X shape as a whole. Approximate.

  Below one end of the four leg members 13a to 13d, one caster 40a to 40d is rotatably provided corresponding to each leg member 13a to 13d. The four leg members 13a to 13d and the four casters 40a to 40d are provided symmetrically vertically and horizontally. As shown in FIGS. 11 and 12, the main body 11a of the leg base 10a has a lower portion positioned near the center of the casters 40a to 40d. Further, the upper surface of the leg base 10a is lower than the leg base 10a shown in FIGS.

(Slide mechanism)
As shown in FIGS. 11 and 12, a front slide groove 20 a is provided on the front wall of the support column 20. Corresponding plate-like first slide plates 22a to 6f are respectively attached to the back surfaces of the third support portion 30a to the eighth support portion 30f. The first slide plate 22a to the sixth slide plate 22f are respectively arranged on the front wall of the support column 20 so as to cover the opening of the front slide groove 20a.

  Hereinafter, the slide mechanism of the third support portion 30a to the eighth support portion 30f of the device storage stand according to the second embodiment will be described by paying attention to the fourth support portion 30b. As shown in the top view of FIG. 13, a regular square cylindrical slide pipe 24 is provided in the center inside the column 20. As shown in FIGS. 13 and 15, the second slide plate 22b is attached to one side surface of a rectangular parallelepiped slide block 52b having a through hole 52b1 penetrating in the vertical direction.

  As shown in FIG. 15, the other side surface of the slide block 52 b opposite to the second slide plate 22 b slides smoothly with the inner surface of the column 20. A regular square cylindrical slide pipe 24 is inserted and provided inside a through hole 52b1 penetrating the slide block 52b in the vertical direction. The inner surface of the through hole 52b1 and the outer surface of the slide pipe 24 slide smoothly with each other.

  In FIG. 14, which corresponds to the cross section seen from the EE direction in FIG. 13, the cross section of the slide block 52b is shown by hatching. As shown in FIG. 14, a slide frame 57b is attached to the right side of the slide block 52b, and an internal slide groove 58b extending in the vertical direction is provided on the slide frame 57b. As shown in FIGS. 13 to 15, a back surface slide groove 20 b extending in the vertical direction is provided on the back wall of the support column 20 so as to overlap the internal slide groove 58 b of the slide frame 57 b. As can be seen from FIG. 14, the width of the back slide groove 20b is narrower than the width of the internal slide groove 58b. Similar to the equipment storage stand according to the first embodiment, the front wall of the support column 20 is not necessarily a flat plane, and is provided with a stepped part in a range that does not hinder the construction of the slide mechanism. It does not interfere with topologies that include structures or cylindrical aspects.

  As shown in FIG. 15, a shaft portion 101 b is inserted into both the slide frame 57 b and the back surface slide groove 20 b so that one end protrudes horizontally from the inside to the outside of the back wall of the support column 20. A second butterfly nut (wing nut) type second slide knob 53b is provided between one end side of the shaft portion 101b that protrudes outward and between the outer surface of the back wall of the support column 20 via a ring washer 59b. Are fitted.

  A male screw is formed on the outer peripheral surface of the shaft portion 101b, a female screw is formed on the inner peripheral surface of the second slide knob 53b, and the shaft portion 101b and the second slide knob 53b are screwed together. A fixed plate 54b is attached to the other end of the shaft portion 101b located inside the back wall of the column 20.

  By rotating the second slide knob 53b in the direction of traveling toward the other end of the shaft portion 101b located inside the support column 20, the slide frame 57b and the support column 20 can be moved between the fixed plate 54b and the washer 59b. A back wall is pinched | interposed and mutually_contact | adhered and the height of the up-down direction of the slide frame 57b inside the support | pillar 20 is fixed. As a result, the height of the fourth support portion 30b is fixed.

  On the other hand, by rotating the second slide knob 53b in the direction of traveling toward one end of the shaft portion 101b located outside the support column 20, the slide frame 57b and the back wall of the support column 20 are fixed to the fixed plate 54b and the washer. It is opened from between 59b and can move in the vertical direction inside the support column 20. The range of movement of the slide frame 57b is limited to the range in which the shaft portion 101b can move in the slide groove, that is, within the vertical length of the slide groove.

  As mentioned above, although it demonstrated as a representative example paying attention to the angle adjustment mechanism of the 4th support part 30b, it is the same also about the other 3rd support part 30a and the 5th support part 30c-8th support part 30f. 11 and 12, the first slide knobs 53a to 53f provided on the third support portion 30a to the eighth support portion 30f, respectively, similarly to the second slide knob 53b of the slide mechanism of the fourth support portion 30b. A sixth slide knob 53f is illustrated. According to the device storage stand according to the second embodiment, as shown in FIG. 16, the third physics device 194a to the eighth chemistry device are slid up and down together with the third support portion 30a to the eighth support portion 30f. 194f can be moved up and down individually.

(How to use the slide mechanism)
For example, the user rotates the second slide knob 53b with the other hand while fixing the fourth support portion 30b with one hand, and the back frame wall of the slide frame 57b and the support column 20 is fixed between the fixing plate 54b and the washer 59b. The fourth support part 30b is slid to a desired height and disposed. Then, while maintaining the height of the arranged fourth support portion 30b, the second slide knob 53b is rotated with the other hand, and the slide frame 57b and the back wall of the support column 20 are placed between the fixed plate 54b and the washer 59b. Put them in close contact with each other. As a result, the height of the fourth support portion 30b disposed after the slide can be fixed even if one hand is separated from the fourth support portion 30b.

  Although different from FIGS. 14 and 15, the slide block 52 b, the slide frame 57 b, and the base unit 31 may be moved with a structure in which the rear slide groove 20 b is not provided. When the base unit 31 is slid, the second slide knob 53b is turned in the loosening direction. When the slide block 52b is moved, the base portion 31 integrated with the slide block 52b is also moved. Since the washer 59b is fixed to the support column 20, even if the slide block 52b moves, the second slide knob 53b, the washer 59b, the fixing plate 54b, and the shaft portion 101b do not move.

  Even in the device storage stand according to the second embodiment, similarly to the device storage stand according to the first embodiment, even if a plurality of physics and chemistry devices are arranged side by side in a high density in the vertical direction, a plurality of adjacent vertical storage devices are provided. It is possible to provide a compact equipment storage stand that can avoid interference with the attachment position of the physics and chemistry equipment and does not impair the operability of each chemistry and chemistry equipment. In particular, even when the sizes of the plurality of physics and chemistry instruments are different from each other, the mutual spacing and angle of the support portions can be adjusted, so that the versatility of mounting the plurality of chemistry instruments is extremely enhanced. As a result, a larger number of physics and chemistry instruments can be safely and reliably attached at a high density to a single instrument storage stand, and space saving at medical sites and the like is possible.

  Moreover, according to the apparatus storage stand which concerns on 2nd Embodiment, since the main body 11a of the leg base 10a is further made low-center of gravity, stability can be improved rather than the case of 1st Embodiment. . Moreover, since the upper surface of the leg base 10a is lower than the leg base 10a in the case of the first embodiment, the overall height of the device storage stand can be reduced and the size can be reduced.

  In addition, according to the device storage stand according to the second embodiment, the third physics and chemistry equipment 194a to the eighth physics and chemistry equipment 194f can be individually moved up and down. Therefore, the 3rd physics equipment 194a-8th physics and chemistry equipment 194f is larger than the 3rd chemistry equipment 93a-8th physics and chemistry equipment 93f shown in Drawing 7, especially the size of the up-and-down direction, and the 3rd physics chemistry equipment 194a-8th Even when the clearance between the physics and chemistry equipment 194f cannot be adjusted by the angle adjustment mechanism alone, it is possible to further cope with it. Therefore, the range of physics and chemistry equipment that can be installed can be expanded regardless of the model or manufacturer. Other effects of the device storage stand according to the second embodiment are the same as those of the device storage stand according to the first embodiment.

(Other embodiments)
As described above, the present invention has been described according to the first and second embodiments. However, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art. Therefore, the present invention naturally includes various embodiments not described herein.

  For example, in the case of the first and second embodiments, as shown in FIG. 10, the external connection terminal 21 is provided on the support column 20. However, the power cable can be configured by directly extending the lines extending from the first outlet 26a, the second outlet 26b, and the third outlet 23a to the eighth outlet 23f without providing the external connection terminal 21 separately. Moreover, the apparatus storage stand according to the present invention can be configured by partially combining the structures of the apparatus storage stands according to the first and second embodiments.

If the power cable is directly extended from the outlet, there will be eight outlets, resulting in a fairly thick power cable. Therefore, as already described as a modification of the first embodiment, the negative and ground lines of the power cable are actually connected directly to the first outlet 26a, and the second outlet 26b and the third outlet 23a to the eighth outlet. If 23f connects between outlets by wiring, it can suppress that a power cable becomes thick.

  As described above, the present invention includes various embodiments and the like that are not described in the present specification and drawings, and the technical scope of the present invention is determined by the invention specifying matters according to the scope of claims reasonable from the above description. It is only determined.

10, 10a Leg base 11, 11a Main body 12a-12d Leg member 13a-13d Leg member 20 Post 20a Front slide groove 20b Back slide groove 21 External connection terminals 22a-22f First slide plate to sixth slide plate 23a-23f First 3 outlets to 8 outlets 24 slide pipe 26a first outlet 26b second outlet 27 power switches 30a to 30f third support part to eighth support part 31 base part 32 rotating shaft 33 rotating drum 34 base 35 crankshafts 36b1 and 36b2 36b6 Angle adjusting plate 37 Follower member 38 Sliding member 39 Stopper plates 40a to 40d Caster 51 Handle 52b Slide block 52b1 Through hole 53a to 53f First slide knob to sixth slide knob 54b Fixed plate 55 Hook 56 Upper support plate 7b Slide frame 58b Internal slide groove 59b Washer 60a First support portion 60b Second support portion 70 Pole 80 Hangers 91a to 91f First mounting base to sixth mounting base 92a to 92f First mounting base to sixth mounting base 93a to 93f 3rd physics and chemistry equipment-8th chemistry and chemistry equipment 94a-94f 3rd physics and chemistry equipment-8th chemistry and chemistry equipment 95a-95f 3rd power cord-8th power cord 96b Fixed frame part 97b Moving block 98b Clamping screw 99b Adjustment knob 101b Shaft part 103b 2nd physics and chemistry equipment 105b 2nd power cord 110 Circuit protector 120 Outlet 130 for external power supply Power cables 194a to 194f 3rd chemistry and chemistry equipment to 8th chemistry and chemistry equipment

In order to achieve the above object, the first aspect of the present invention provides:
(a) A device storage stand that allows n physics and chemistry devices of different sizes to be stored side by side in the vertical direction, where n is a positive integer of 3 or more,
(b) a cylindrical column having a front wall including at least a part of a flat plane extending in the vertical direction;
(c) n base portions each having a concave portion with an open top and provided on the front wall ;
(d) n rotating shafts provided one by one in the recess and supported at both ends by the base so as to bridge between the opposing side walls constituting the recess;
(e) n rotating drums, each of which is attached as a part of the angle maintaining device so as to surround each of the n rotating shafts, and is arranged concentrically with the rotating shaft;
(f) a base having a longitudinal direction in a direction perpendicular to the rotation axis, n base portions that are respectively rotatable around the rotation shaft as a fulcrum inside the recess while exposing the upper end from the base portion;
(g) n support portions that are located outside the base portion, connect the lower end of the rod shape to the upper end, and can rotate together with the base as a fulcrum;
(h) n fixing frame portions fixed to the n supporting portions one by one with a tightening screw ;
(i) an attachment base that is fixed to each of the n fixed frame portions and arbitrarily mounts any of the n physics and chemistry instruments ;
The angle maintaining device is characterized in that the mounting angle is adjusted by independently maintaining the mounting angles of the n support portions with respect to the axial columns .
The second aspect of the present invention includes
(a) A device storage stand that allows n physics and chemistry devices of different sizes to be stored side by side in the vertical direction, where n is a positive integer of 3 or more,
(b) a cylindrical column having a front wall including at least a part of a flat plane extending in the vertical direction;
(c) n slide plates arranged so as to cover the openings of n front slide grooves provided on the front wall, each slidable in a vertical direction along a flat plane;
(d) n base portions each having a concave portion with an open top, each fixed to each of the n slide plates ;
(e) n rotating shafts provided one by one in the recess and supported at both ends by the base so as to bridge between the opposing side walls constituting the recess;
(f) n rotating drums attached as a part of the angle maintaining device one by one so as to surround each of the n rotating shafts, each being arranged concentrically with the rotating shaft;
(g) n-shaped bases each having a rod-like shape whose longitudinal direction is perpendicular to the rotation axis and being rotatable from the rotation axis as a fulcrum inside the recess while exposing the upper end from the base part;
(h) n support parts that are located outside the base part, connect the lower end of the rod shape to the upper end, and can rotate together with the base as a rotation axis;
(i) n fixing frame portions fixed to the n supporting portions one by one with a tightening screw ;
(j) an attachment base fixed to each of the n fixed frame portions and arbitrarily mounting any of the n physics and chemistry instruments ;
The angle maintaining device maintains the mounting angle of the n support portions with respect to the axial support column independently of each other, so that the vertical direction of the slide plate corresponds to the size of each of the n physics and chemistry instruments. The position and the mounting angle are adjusted .

Claims (12)

A strut having a front wall and extending vertically;
Each of the plurality of support parts has a base part and supports three or more stages of physics and chemistry equipment arranged in the vertical direction along the front wall, each of the support parts being a base A plurality of support portions, each of which includes a rotating shaft, the base portion includes a rotation shaft, and each of the support portions is rotatable about the rotation shaft.
An angle adjustment mechanism that independently adjusts an attachment angle of each of the plurality of support portions to the column in the axial direction;
A device storage stand comprising:   2. The device storage stand according to claim 1, wherein the range of the mounting angle is 0 ° or more and 50 ° or less.   The apparatus storage stand according to claim 1, further comprising an angle maintaining device that maintains the attachment angle at a constant value.   When the physics and chemistry instrument is attached to the support part in a state in which the maintenance of the attachment angle is released, the apparatus further comprises a movement speed relaxation device that moderates the movement speed below the support part due to the weight of the physics and chemistry instrument. The equipment storage stand according to claim 3.   The apparatus storage stand according to any one of claims 1 to 4, further comprising a plurality of power outlets corresponding to each of the plurality of support portions.   6. The equipment storage stand according to claim 5, wherein the support column has a cylindrical shape, and the plurality of power outlets are built inside the support column.   The apparatus storage stand according to claim 1, further comprising a slide mechanism that adjusts a position of the support portion in a vertical direction.   The leg base further includes a leg base that stands upright in the vertical direction, and the leg base includes a plate-like main body and a plurality of leg members that project outward from the main body. The apparatus storage stand as described in any one of 1-7.   When the plurality of physics and chemistry instruments are attached to the plurality of support portions by adjusting the respective attachment angles, the plurality of physics and chemistry instruments are positioned inside the leg base as viewed from the side. 9. The apparatus storage stand according to claim 8, wherein the support column is attached to be unevenly distributed with respect to the center of the leg base.   The apparatus storage stand according to claim 9, wherein a width of the leg base is longer than a width of a hanger provided on an upper portion of the support column.   The equipment storage stand according to claim 9 or 10, wherein the leg base further includes a caster rotatably attached to each of the plurality of leg members.   The equipment storage stand according to claim 11, wherein a center of gravity of the leg base is provided at a position lower than an upper surface of the caster.

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