JP6453080B2 - Chemical supply device - Google Patents

Description

  The present invention relates to a chemical solution supply apparatus, for example, a chemical solution supply apparatus used by a patient himself like subcutaneous injection of insulin or the like.

For example, in diabetic patients, etc., it is common practice that patients themselves inject insulin or the like subcutaneously. In these drug supply devices (syringes) used by these patients themselves, a plurality of drug solution amounts are accommodated in the drug solution supply device (syringe), and after the user sets a single dose, the above-mentioned by injection Some drugs are administered.
Since this chemical solution supply device (syringe) is used by the patient himself (to make an injection), the operation thereof must be simple and the amount of the chemical solution must be accurately administered. In addition, when the drug solution supply device (syringe) is not reused but is disposable, the patient is very expensive and must be inexpensive.

  As this drug solution supply device (syringe), for example, as shown in Patent Documents 1 and 2, a patient rotates a rotary knob, sets a dose, and then pushes down a release knob different from the rotary knob. A chemical solution supply device (syringe) for administering a chemical solution is known.

Japanese Patent No. 4922172 Japanese Patent Publication No. 6-24600

By the way, in the chemical solution supply device (syringe) shown in Patent Documents 1 and 2, the patient sets the dosage by rotating the rotary knob of the chemical solution supply device (syringe), and then pushes down the release knob. Therefore, it is necessary to set the dose and administer the chemical solution using different members.
Such a chemical solution supply device (syringe) is difficult to operate, for example, for persons with visual impairment found in diabetic patients and the like, and the number of parts constituting the chemical solution supply device (syringe) increases, resulting in an increase in cost. There was a technical problem.

  The present invention has been made in order to solve the above technical problem, and by performing the setting of the dosage and the administration of the chemical solution with a single member, the chemical solution can be operated more easily and the number of components is suppressed. An object is to provide a supply device.

A chemical solution supply device according to the present invention is a chemical solution supply device that supplies a chemical solution by storing a chemical solution in a shaft tube and moving a piston in the shaft tube in a forward direction of the shaft tube, and An operation portion that is pulled backward from the rear end portion of the shaft cylinder by rotating and moved forward by being pushed in, and provided in the rear end portion of the shaft tube and rotated in one direction of the operation portion And a screw portion that engages with a first protrusion formed at the front end portion of the operation portion, and in a state where the operation portion is pulled out in the rearward direction, the crown portion is associated with the crown portion. In a state where the rotation is prohibited and the operation portion is pushed forward, the rotor is disengaged from the crown portion and rotated by the first protrusion of the operation portion, and the rotor and a piston rod that rotates together with, the rotation of the piston rod , And a motion converter for moving the piston formed at the front end of the piston rod and the piston rod in the forward direction, by rotating the operation unit in one direction, from the rear end of the barrel Pulling back and pushing in the operation unit, the rotor and the piston rod are rotated, the piston rod and the piston are moved forward through the motion conversion unit, and a chemical solution is supplied. Yes.

The chemical solution supply device rotates the operation portion in one direction, pulls it backward from the rear end portion of the shaft tube, pushes the operation portion, rotates the rotor and the piston rod , and converts the motion. The piston rod and the piston are moved in the forward direction via the section, and the chemical solution is supplied.
Therefore, by rotating the operation unit in one direction (for example, one rotation), the operation unit is pulled out and the dose is set. Further, the drug solution can be administered by pushing in the operation unit (returning to the original state before pulling out).
That is, the dose can be set and the drug solution can be administered with a single member, which can be operated more easily, and the number of parts can be further suppressed, so that an inexpensive drug solution supply apparatus can be obtained.

Here, a second projecting portion formed in the outer peripheral surface of the operation portion and extending in the radial direction and extending in the front-rear direction of the inner peripheral surface of the crown portion, one surface in the circumferential direction is inclined. And the other surface is a vertical surface, and when the operation portion rotates in one direction, the second protrusion and the inclined surface abut, When the second projecting portion is sunk in the radial direction, the operation portion is allowed to rotate. When the operation portion is rotated in the other direction, the second projecting portion and the vertical surface are in contact with each other. The rotation of the operation unit is preferably prohibited.

  Thus, since the operation unit is allowed to rotate in only one direction, it is possible to prevent an erroneous dose setting. For example, when the operation unit is rotated in one direction and the dose is set, the operation unit is rotated in the other direction (reverse direction), and the operation unit is rotated again in one direction. Therefore, by prohibiting the operation unit from rotating in the other direction, it is possible to prevent discharge of an erroneous dose as described above.

A concave portion or a convex portion formed at a front end of the crown portion; a convex portion or a concave portion formed at a rear end of the rotor that engages the concave portion or convex portion of the crown portion; and the rotation. A spring that presses the rear end of the child against the front end of the crown, and by the biasing force of the spring, the crown and the rotor are engaged, and the operation part is pushed in, The first protrusion of the operating portion moves the rotor forward against the biasing force of the spring via the screw portion of the rotor, and the engagement between the crown and the rotor is released. It is desirable.
With this configuration, when the operation unit is not pushed in, the crown and the rotor are engaged, so the rotor (and piston) does not rotate and the chemical solution is supplied. Not. On the other hand, since the engagement between the crown and the rotor is released by pushing in the operation part, the rotor (and the piston) rotates, the piston moves forward, and the chemical solution is supplied.

Further, the piston is formed at a front end portion of the rotor, the piston rod having a piston portion having an opposing flat portion extending behind the piston and a screw portion formed between the flat portions. Motion conversion, which has the same shape as the cross-sectional shape of the rod, a through-hole through which the piston rod is inserted, and a screw portion that is fixed to the shaft cylinder and screwed with the screw portion of the piston rod on the inner peripheral surface It is preferable that the piston rod is rotated together with the rotation of the rotor, the piston rod and the piston are moved forward by the motion conversion unit, and the chemical solution is supplied.
By comprising in this way, the said rotor and piston rod rotate, the said piston can be advanced, and a chemical | medical solution can be supplied.

  According to the present invention, it is possible to obtain a chemical solution supply apparatus that can be operated more easily and the number of parts is suppressed by setting the dose and administering the chemical solution with one member.

FIG. 1 is an external perspective view showing an embodiment of a chemical liquid supply apparatus according to the present invention. 2 is a partial cross-sectional view of the embodiment shown in FIG. FIG. 3 is a cross-sectional view showing a state (initial state) before the operation of the embodiment shown in FIG. 1 is started. 4A and 4B are diagrams showing the operation unit of the embodiment shown in FIG. 1, wherein FIG. 4A is a perspective view seen from the front, FIG. 4B is a perspective view seen from the rear, and FIG. is there. FIGS. 5A and 5B are views showing the crown portion of the embodiment shown in FIG. 1, wherein FIG. 5A is a perspective view seen from the front, FIG. 5B is a side view, and FIG. 6 is a view showing the rotor of the embodiment shown in FIG. 1, wherein (a) is a perspective view seen from the rear, (b) is a sectional view, and (c) is an angle of 90 degrees with (b). Are cross-sectional views different from each other, and FIG. FIG. 7 is a perspective view of the piston rod (piston) of the embodiment shown in FIG. 1 as viewed from the rear. FIG. 8 is a schematic perspective view showing a process of the operation of the embodiment shown in FIG. 1, and shows a state before starting the operation (initial state). FIG. 9 is a cross-sectional view illustrating a state in which the operation unit is pulled out in the embodiment illustrated in FIG. 1. FIG. 10 is a schematic perspective view for explaining that the piston moves forward by pushing the operation unit in the embodiment shown in FIG. 1, and (a) is a perspective view showing the relationship between the operation unit and the rotor. (B) is a perspective view which shows the relationship between a piston rod and a motion converter.

Hereinafter, an embodiment of a chemical solution supply apparatus according to the present invention will be described with reference to FIGS. 1 to 10.
First, based on FIG. 1, FIG. 2, the chemical | medical solution supply apparatus and the syringe by which this chemical | medical solution supply apparatus is used are demonstrated.
As shown in FIGS. 1 and 2, reference numeral 1 denotes a syringe that contains a plurality of doses of a drug solution and administers the drug by injection after the user sets a dose for one dose. The syringe 1 includes a syringe unit 2 and a chemical solution supply device 3.

The injection part 2 is disposed in the front shaft cylinder 2a and protrudes outside from the distal end of the front shaft cylinder 2a and contains a chemical solution storage part 2b that stores a plurality of times of the drug solution quantity. Has a needle portion 2c. The front shaft cylinder 2a is formed with a window portion 2d for confirming the amount of the chemical solution stored in the stored chemical solution storage portion 2b.
The chemical solution storage unit 2b includes a cylinder that stores the chemical solution therein, and is configured such that a chemical solution is supplied to the patient when a piston 36b described later moves forward in the cylinder.

As shown in FIGS. 2 and 3, the chemical solution supply device 3 includes a rear shaft tube 31 fitted and fixed to the front shaft tube 2 a, and a rear direction from the rear end portion 31 a of the rear shaft tube 31. It is provided with an operation unit 32 that is pulled out and moved forward by being pushed. In the description of the present embodiment, as shown in FIG. 2, the direction from the operation part 32 toward the needle part 2c (X1 direction) is the front direction, and the direction from the needle part 2c toward the operation part 32 (X2 direction) is the rear direction. It is called direction.
The chemical solution supply device 3 is provided at the rear portion of the rear barrel 31 and allows the crown 30 to be rotated in one direction, and engages or disengages the crown 33. A rotor 34 that is in a combined state is provided.

The rotor 34 engages with the crown portion 33 when the operation portion 32 is pulled out backward, and engages with the crown portion 33 when the operation portion 32 is pushed forward. Is released and is configured to rotate.
Engagement or disengagement (release of engagement) between the crown portion 33 and the rotor 34 is performed by a spring 35 that presses the rear end of the rotor 34 against the front end of the crown portion 33. In other words, the rear end of the rotor 34 is pressed against the front end of the crown portion 33 by the spring 35, so that the crown portion 33 and the rotor 34 are engaged.
On the other hand, when the operating portion 32 is pushed, the rotor 34 moves forward while compressing the spring 35, and the engagement between the crown portion 33 and the rotor 34 is released (the state is disengaged). )

  In addition, the chemical liquid supply device 3 includes a piston 36b provided at the tip of a piston rod 36 that rotates together with the rotor 34, and a motion conversion unit that converts the piston rod 36 (piston 36b) into a forward movement. 37.

Furthermore, each member which comprises the said chemical | medical solution supply apparatus 3 is demonstrated.
First, the operation unit 32 will be described with reference to FIG.
The operation unit 32 is provided on a front side of the grasping unit 32a, and is engaged and disengaged with the crown portion 33, by a user such as a patient grasping and performing rotation and push-in operations. An in-crown insertion portion 32b is provided, and an in-rotor insertion portion 33c is provided on the front side of the canopy insertion portion 32b and rotates the rotor when pushed.

The grip portion 32a is formed in a cylindrical shape, and is easily gripped and rotated by a user such as a patient, and the rear end surface is formed flat and easy to push.
The inner crown portion insertion portion 32b is formed in a cylindrical shape having an outer diameter smaller than that of the grip portion 32a, and a second protrusion portion 32d protruding and protruding in the radial direction is formed on the outer peripheral surface thereof.
The protrusion 32d is formed on the upper surface of the plate-like portion 32f surrounded by the U-shaped second slit 32e. Therefore, when an external force is applied to the second protrusion 32d, the plate-like portion 32f is deformed radially inward, and the second protrusion 32d is sunk from the outer peripheral surface.
On the other hand, when the external force is removed, the plate-like portion 32f returns to the original state, and the second protrusion 32d is formed so as to protrude from the outer peripheral surface.

The rotor inner insertion portion 32c is formed in a cylindrical shape having an outer diameter smaller than that of the crown crown inner insertion portion 32b, and a screw portion 34a (see FIG. 3 and FIG. 6), a spiral first protrusion 32g is formed.
Therefore, by rotating the operation portion 32 in one direction, the first protrusion 32g moves backward in the screw portion 34a of the rotor 34, and the operation portion 32 moves from the rear end portion of the shaft tube 31 to the rear. Pulled in the direction.

  Further, a first slit 32h extending in the axial direction is formed between the first protrusions 32g. The first slit 32h is formed so that the first protrusion 32g is deformed radially inward to facilitate insertion of the crown portion 33 into the through hole 33e.

Next, the crown portion 33 will be described with reference to FIG.
The crown portion 33 is provided at the rear end portion of the rear barrel 31 and allows the operation portion 32 to rotate in one direction.
The crown portion 33 is formed in a cylindrical shape, and includes a ring-shaped locking portion 33a that is locked to the rear end surface of the rear shaft tube 31, and a projection portion 33b that is formed on the peripheral surface. The projection 33b is fitted into a through hole 31b (see FIG. 1) formed in the rear shaft cylinder 31, and the locking portion 33a is locked to the rear end surface of the rear shaft cylinder 31, thereby The crown portion 33 is fixed to the rear shaft tube 31.

Further, as shown in FIG. 5B, the inner peripheral surface of the crown portion 33 is extended in the front-rear direction, one surface in the circumferential direction is formed in the slope portion 3c1, and the other surface is vertical. A plurality of convex portions 33c formed on the surface 3c2 are provided.
The convex portion 33c and the projection portion 32d of the operation portion 32 are engaged with each other. That is, when a force (rotation force of the user) that rotates in one direction (the formation direction of the slope portion 3c1) acts on the operation portion 32, the projection portion 32d contacts the slope portion 3c1, and the plate-like portion 32f is deformed. Then, the second protrusion 32d can be sunk from the outer peripheral surface, and the operation part 32 can be rotated. Then, when the rotational force (user's rotational force) in one direction (the formation direction of the slope portion 3c1) of the operation portion 32 is stopped, the plate-like portion 32f returns to the original state, and the second protrusion 32d. Protrudes from the outer peripheral surface (returns to its original state) and engages with the convex portion 33c.

  On the other hand, when a force (rotational force of the user) that rotates in the other direction (the formation direction of the vertical surface 3c2) is applied to the operation portion 32, the projection 32d and the vertical portion 3c2 come into contact with each other, and the plate-like portion 32f Does not deform. Therefore, the second projecting portion 32d is locked to the convex portion 33c without being submerged from the outer peripheral surface, and the rotation of the operation portion 32 is prohibited.

A concave portion 33 d is formed in the front portion of the crown portion 33. The concave portion 33d is engaged with a convex portion 34b (see FIG. 6) formed on the rotor 34, and prevents the rotation of the rotor 34 when the operation portion 32 is pulled out while rotating. That is, when the first protrusion 32g of the operation unit 32 rotates and moves in the screw portion 34a of the rotor 34, the rotation of the operation unit 32 prevents the rotor 34 from rotating. Is.
In this embodiment, as described above, the concave portion 33d is formed in the crown portion 33 and the convex portion 34b is formed in the rotor 34. However, the convex portion is formed in the crown portion 33. And a recess may be formed in the rotor 34.
In addition, a through hole 33 e through which the rotor insertion portion 32 c of the operation portion 32 is inserted is formed at the front end of the crown portion 33.

Next, the rotor 34 will be described with reference to FIG.
The rotor 34 is formed in a cylindrical shape, and is formed on the inner peripheral surface of the rear portion of the rotor 34. The screw portion 34 a that engages with the first protrusion 32 g of the operation portion 32, and the rear of the rotor 34. A convex portion 34 b is formed at the end to engage with the concave portion 33 d of the crown portion 33.
The convex portion 34b is formed on the rear surface of the flange portion 34c having a larger outer diameter than the outer diameter of the screw portion 34a. As described above, a convex portion may be formed on the crown portion 33 and a concave portion may be formed on the rotor 34.

As shown in FIG. 3, one end of the spring 35 is locked to the front surface 34 c 1 (front side surface) of the flange portion 34 c of the rotor 34. The other end of the spring 35 is locked to the step portion 31 c of the rear shaft cylinder 31. As a result, the rotor 34 is urged toward the crown portion 33 by the spring 35, and the convex portion 34 b is engaged with the concave portion 33 d of the crown portion 33.
The lead angle θ (see FIG. 6C) of the screw portion 34a is set to 45 degrees or more so that the rotor 34 is rotated by the advancement of the first protrusion 32g. When the lead angle θ is set to 45 degrees or less , the rotor 34 does not rotate due to the forward movement of the first protrusion 32g, so that the operation unit 32 is pushed in (the operation unit 32 Cannot move forward).

The front end surface of the rotor 34 is formed with a through hole 34d having the same shape as the cross-sectional shape of the piston rod 36 and through which the piston rod 36 is inserted. That is, a through hole 34d having a planar portion 34d1 facing each other and a curved portion 34d2 formed between the planar portions is provided.
Therefore, the rotor 34 and the piston rod 36 rotate together with the piston rod 36 coming into contact with the flat surface portion 34d1. On the other hand, since the through hole 34d has the same shape as the cross-sectional shape of the piston rod, the piston rod 36 can move in the forward direction with respect to the rotor 34 via the motion converting portion 37.

Next, the piston rod 36 will be described with reference to FIG.
The piston rod 36 includes a cylindrical screw portion 36a and a cylindrical piston 36b formed at the tip of the screw portion 36a. The piston rod 36a includes a planar portion 36a1 facing each other and a screw forming portion 36a2 formed between the planar portions 36a1.
Since the piston rod 36 is formed in the shape, the piston rod 36 rotates together with the rotor 34. However, the piston rod 36 moves forward with respect to the rotor 34 via a motion conversion unit 37. It is configured to be able to move.
The piston 36b is configured such that the chemical liquid is supplied to the patient by advancing in a cylinder that stores the chemical liquid therein.

Next, the spring 35 and the motion converter 37 will be described with reference to FIG.
As shown in FIG. 3, the spring 35 is locked to the front surface 34c1 of the flange portion 34c of the rotor 34 and the step portion 31c of the rear shaft cylinder 31, and urges the rotor 34 toward the crown portion 33 side. doing. That is, the convex portion 34 b of the rotor 34 is engaged with the concave portion 33 d of the top crown portion 33.
Therefore, when the operating portion 32 is pulled out from the rear barrel 31 while rotating the operating portion 32, the convex portion 34 b is the concave portion of the crown portion 33 even if the rotational force of the operating portion 32 is transmitted to the rotor 34. Since it is locked to 33d, the rotor 34 does not rotate. On the other hand, when the operation unit 32 is pushed in, the rotor 34 moves forward while compressing the spring 35, and the engagement between the crown portion 33 and the rotor 34 is released (disengaged). ), The rotor 34 rotates.

Further, the motion converting portion 37 is formed in a cylindrical shape, and a screw portion 37a that is screwed with the screw forming portion 36a2 of the piston rod 36 is formed on the inner peripheral surface thereof. Further, the motion converting portion 37 is fixed to the rear shaft tube portion 31.
Therefore, when the piston rod 36 is rotated, the piston rod 36 is moved forward by the motion conversion unit 37. That is, as described above, the rotor 34 and the piston rod 36 rotate as a unit, and the piston rod 36 is moved forward relative to the rotor 34 by the motion converter 37.

Next, the operation and action of the chemical solution supply apparatus will be described with reference to FIGS. In the schematic diagrams of FIGS. 8 and 10, the shaft cylinder 31 is omitted.
First, as shown in FIG. 8, the operation unit 32 is rotated in one direction (R direction). When a force (rotating force of the user) that rotates in one direction (R direction, the formation direction of the slope portion 3c1) is applied to the operation portion 32, the projection portion 32d contacts the slope portion 3c1, and the plate-like portion 32f is deformed. The second protrusion 32d can be immersed from the outer peripheral surface and rotated. At this time, since the rotor 34 is urged by the spring 35 to the crown portion 33, the rotor 34 does not rotate even if the operation unit 32 is rotated.

When the first protrusion 32g of the operation portion 32 rotates (R direction), the operation portion 32 is moved rearward (X2 direction) from the rear end portion of the rear barrel 31 by the screw portion 34a of the rotor 34. Pulled out.
And as shown in FIG. 9, when the operation part 32 carries out predetermined rotation (for example, 1 rotation), the chemical | medical solution amount for 1 time is set. It should be noted that the piston rod 36 is not affected at all by the rotation and pulling-out operation of the operation portion 32 (it is not pulled out backward) and remains in the current position.

  Further, when the first protrusion 32g is positioned at the rear end of the screw portion 34a and is prevented from being pulled out (moved) in the rearward direction, the first protrusion 32g is screwed by the first slit 32h. Overcoming the thread of the part 34a, the operation part 32 is so-called idle, and the operation part 32 and the rotor 34 are prevented from being damaged.

  On the other hand, if the operation unit 32 is rotated in the other direction (the direction opposite to the R direction) during the rotation of the operation unit 32, the projecting portion 32d and the vertical portion 33c2 come into contact with each other, and the plate-like portion 32f is not deformed. For this reason, the second protrusion 32d does not sink from the outer peripheral surface, but is locked to the convex portion 33c, and the operation portion 32 cannot be rotated.

Then, as shown in FIG. 10A, the operation unit 32 is pushed in the forward direction (X1 direction) from the state in which the operation unit 32 is pulled out until it comes into contact with the crown portion 33.
By pushing the operating portion 32, the first protrusion 32 g of the operating portion 32 moves the rotor 34 forward via the screw portion 34 a and resists the urging force of the spring 35, while The engagement between the portion 33 and the rotor 34 is released. That is, the rotor 34 is brought into a rotatable state.
As a result, the rotor 34 is rotated by the pushing operation of the operation unit 32 (the movement of the first protrusion 32g in the forward direction (X1 direction)).

Further, since the piston rod 36 is configured to be rotatable integrally with the rotor 34, the piston rod 36 rotates with the rotation of the rotor 34, as shown in FIG. Further, since the piston rod 36 is screwed with the fixed motion converting portion 37, the piston rod 36 moves forward (moves in the X1 direction) by the rotation of the piston rod 36.
The piston 36b is moved forward by the advance of the piston rod 36, and one dose of drug solution is supplied from the drug solution storage unit 2b in the syringe unit 2 and administered to the patient.

  In the case of use again, the above-described operation is repeated. However, in the rotation and pulling-out operation of the operation unit 32, the piston rod 36 (piston 36b) is not affected at all (without moving backward). In order to remain at the current position, the piston 36b gradually advances each time the above-described operation is repeated, and the chemical solution is supplied until the chemical solution in the chemical solution storage unit 2b in the syringe unit 2 is completed.

DESCRIPTION OF SYMBOLS 1 Syringe 2 Injection | pouring part 3 Chemical solution supply apparatus 31 Rear part cylinder 32 Operation part 32d 2nd protrusion part 32g 1st protrusion part 33 Crown part 33c Convex part 33d Concave part 34 Rotor 34a Screw part 34d Through-hole 35 Spring 36 Piston Rod 37 Motion conversion part

Claims (4)

A chemical solution supply apparatus for supplying a chemical solution by storing a chemical solution in a shaft tube and moving a piston in the shaft tube in a forward direction of the shaft tube,
An operation unit that is pulled out in the rear direction from the rear end portion of the shaft cylinder by rotating in one direction and moves in the front direction by being pushed in;
A crown portion that is provided at a rear end portion of the shaft tube and allows one-way rotation of the operation portion;
A screw portion that is screwed with a first protrusion formed at a front end portion of the operation portion, and in a state in which the operation portion is pulled out backward, the crown portion is engaged and rotation is prohibited; In a state where the operation unit is pushed forward, the engagement with the crown can be released, and a rotor that is rotated by the first projection of the operation unit;
A piston rod that rotates with the rotor;
Rotation of the piston rod, and a motion converter for moving the piston formed at the front end of the piston rod and the piston rod in the forward direction,
With
By rotating the operation part in one direction, pulling backward from the rear end of the barrel, pushing the operation part, rotating the rotor and piston rod, via the motion conversion part, A chemical liquid supply apparatus, wherein a chemical liquid is supplied by moving a piston rod and a piston forward. A second protrusion formed on the outer peripheral surface of the operation portion and projecting in the radial direction;
A convex portion that extends in the front-rear direction of the inner peripheral surface of the crown portion, one surface in the circumferential direction is formed as a slope portion, and the other surface is formed as a vertical surface;
With
When the operation unit is rotated in one direction, the second protrusion and the inclined surface are in contact with each other, and the second protrusion is submerged in the radial direction, so that the operation unit is allowed to rotate. ,
2. The chemical solution supply apparatus according to claim 1, wherein when the operation unit is rotated in another direction, the second protrusion and the vertical surface are in contact with each other, and rotation of the operation unit is prohibited. . A recess or projection formed at the front end of the crown,
A convex or concave portion formed at the rear end of the rotor that engages with the concave or convex portion of the crown,
A spring that presses the rear end of the rotor against the front end of the crown,
With
By the urging force of the spring, the crown and the rotor are engaged,
By pushing in the operation portion, the first protrusion of the operation portion moves the rotor forward against the biasing force of the spring via the screw portion of the rotor, and the crown portion and The chemical solution supply apparatus according to claim 1, wherein the engagement of the rotor is released. A piston rod having the piston, a planar portion opposed to each other, and a screw portion formed between the planar portions, and extending rearward of the piston;
A through hole formed at the front end of the rotor, having the same shape as the cross-sectional shape of the piston rod, and through which the piston rod is inserted;
A motion conversion unit fixed to the shaft cylinder, and formed with a screw part screwed with a screw part of a piston rod on an inner peripheral surface;
With
The piston rod is rotated together with the rotation of the rotor, the piston rod and the piston are moved forward by the motion conversion unit, and the chemical solution is supplied. Chemical supply device.

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