JPH0241173A - Syringe pump - Google Patents

Abstract

PURPOSE:To prevent the invasion of water in a syringe pump main body by eliminating the communication part of a clamp insert part and the interior of the syringe pump main body by mounting a slider control mechanism and the slider engaged with the piston part of a syringe and receiving the control signal from the control mechanism to advance the piston part. CONSTITUTION:A magnetoelectric converter element, for example, a Hall IC 37 is arranged in a syringe pump main body 1 in opposed relation to the moving range of a magnet 34 and the magnetism from the magnet 34 is detected by said Hall IC 37. The Hall IC 37 converts the detected magnetism and an electric signal to send said signal to a slider 7 as the control signal corresponding to the size of a syringe 3. The slider 7 receives said control signal to be controlled in its moving distance and, by this method, the moving distance of the piston part 3b in the syringe 3, that is, the feed-out amount of the aqueous solution from the syringe 3 is controlled. After an O-ring 40 is fitted to the upper case groove provided to an upper case 2a, said case 2a is connected to a lower case 2b and, therefore, the invasion of water in the syringe pump main body can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a syringe pump that delivers a constant flow rate of an aqueous solution such as a drug solution to a patient at a constant time from a syringe containing an aqueous solution such as a drug solution.

[Prior Art] Conventionally, in this type of syringe pump, an aqueous solution is supplied in the following manner. That is, first, a syringe containing an aqueous solution is placed on the syringe holding part, the flange part of this syringe is fitted into the engagement groove provided on the syringe holding part, and the piston part is engaged with the engagement part provided on the slider. This fixes the syringe to the syringe pump. After adjusting the flow rate of the aqueous solution sent to the patient, the clamp section is attached to the clamp insertion section provided on the pump body, and the syringe is held down from above by the clamp section and fixed to the syringe body. The height of this syringe is detected by a photosensor provided inside the clamp insertion part and the syringe pump body, and this detection signal is further sent to the slider as a control signal, which determines the moving distance of the slider and The flow rate delivered from the pump is adjusted. Thereafter, when the drive motor is driven to rotate, the slider mechanism is operated, thereby sending a constant flow rate of the aqueous solution from the syringe to the patient via the tube at a constant time.

[Problems to be Solved by the Invention] In the conventional syringe pump as described above, when the syringe is used, an aqueous solution such as a drug contained in the syringe adheres to the surface of the main body case of the syringe pump. Water or hot water is used to remove dirt from the surface.

However, in the conventional syringe pump, since the sensor included in the clamp part is a photosensor, it is necessary to provide communication between the clamp insertion part and the inside of the syringe pump body. Therefore, if water, etc. used to remove dirt on the surface mentioned above enters the clamp insertion part, or if an aqueous solution, etc. in the syringe enters the clamp insertion part directly, this water, etc. will be transferred from the clamp insertion part to the syringe pump. They sometimes penetrate into the main body through the communication part with the main body, causing various problems such as the following. In other words, the electrical system is shorted and the CP
U goes out of control, causing the syringe pump mechanism to go awry, causing it to stop functioning and causing inaccurate measurements. Additionally, the wiring etc. corrode and break, causing the syringe pump to stop working. Furthermore, if the aqueous solution used in the syringe enters the syringe pump body, the odor of the aqueous solution will be trapped inside the syringe body, and furthermore, when the water in the aqueous solution evaporates, the aqueous solution will remain as a white lump, which may become entangled with the drive motor etc. , the drive motor stops working,
The syringe pump also stops moving.

The present invention has been made in view of such problems, and includes:
It is an object of the present invention to provide a syringe pump in which there is no communication part between the clamp insertion part and the inside of the syringe pump body, so that there is no fear of water etc. entering the inside of the body, and the occurrence of various troubles as described above can be prevented. purpose.

[Means for Solving the Problems] In order to solve the above-mentioned conventional problems, the present invention provides a syringe pump that pumps out a constant flow rate of an aqueous solution at a constant time from a syringe containing an aqueous solution, the syringe pump body; a syringe holding portion comprising a syringe mounting groove provided on the syringe pump body and an engagement groove into which a flange portion of the syringe is engaged; a clamp insertion portion provided on the syringe pump body; and the clamp insertion portion. a clamp part that is attached to the syringe holding part and that fixes the syringe held in the syringe holding part from above and moves up and down according to the size of the syringe; a slider consisting of a magnetic generator that moves up and down along with the syringe, and a magnetoelectric transducer that is disposed within the syringe pump body and detects magnetism from the magnetic generator and outputs a control signal according to the size of the syringe. It is characterized by comprising a control mechanism and a slider that engages with the piston portion of the syringe and pushes the piston portion forward in response to a control signal from the control mechanism. In this case, it is preferable to provide a magnetic shielding plate on the back surface of the clamp insertion part or to provide a space between the clamp insertion part and the syringe pump body.

[Function] In the syringe pump according to the present invention with the above configuration, the magnetic sensor constituting the slider control mechanism is provided inside the clamp insertion part and the syringe pump body through the housing of the clamp insertion part, so that it is different from the conventional one. The housing between the clamp insertion part and the syringe pump body, which were in communication with the syringe pump, can be sealed, thus preventing unnecessary water and aqueous solutions from entering the syringe pump body from the clamp insertion part. . Further, by providing an air shielding plate on the back surface of the clamp insertion portion and providing a space between the clamp insertion portion and the syringe pump body, it is possible to prevent external influences on the magnetic sensor.

[Example] Hereinafter, an example of the present invention will be specifically described with reference to the drawings.

FIG. 3 is a perspective view showing the overall structure of a syringe pump according to an embodiment of the present invention, and FIG. 4 is a plan view showing a state in which a syringe is installed in this syringe pump. In the figure, a syringe pump main body 1 consists of an upper case 2a and a lower case 2b, and a syringe holding part 4 for holding a syringe 3 is provided on the upper surface of the upper case 2a. This syringe holding part 4 includes a syringe mounting groove 5 having a substantially semicircular cross section for mounting the syringe 3, and a flange part 3a of the syringe 3.
Engagement grooves 6 for fitting are respectively formed.

The piston portion 3b of the syringe 3 placed in the syringe placement groove 5 is engaged with the engaging portion 8 of the slider 7, and as the slider portion 7 moves back and forth, the syringe 3 The piston portion 3b is configured to reciprocate.

That is, the forward movement of the syringe 3 (to the left in Fig. 4)
As a result, the piston portion 3b of the syringe 3 is pushed forward, and as a result of the movement of the piston portion 3b, the aqueous solution stored inside is transferred from the syringe 3 at a constant flow rate at a constant time through a tube (not shown) connected to the syringe 3. It is injected into the patient.

A clamp part 9 is provided at the upper part of the syringe holding part 4, and the syringe 3 held by the syringe holding part 4 is pressed down and fixed from above by this clamp part 9. Figure 1 shows the clamp part 9 along line I-I in Figure 4.
FIG. 2 shows a cross-sectional structure taken along line II--II in FIG. 4. This clamp part 9 is inserted into a clamp insertion part 30 provided on the surface of the upper case 2a of the syringe pump main body 1, and includes a cap part 31 that covers the opening of the clamp insertion part 30, and a cap part 31 that covers the opening of the clamp insertion part 30. It is composed of a clamp shaft 32 that penetrates and is inserted into the clamp insertion part 30, and a clamp 33 that is provided on the upper part of the cap part 31 and presses the syringe 3 from above. The upper end of the clamp shaft 32 abuts against the clamp 33, and a magnet 34 constituting a magnetic sensor is disposed at the lower end. Further, a compression coil spring 35 is wound around the outer circumference of the clamp shaft 32, and the upper end of the compression coil spring 35 abuts against the upper surface of the cap portion 31, and the lower end abuts against the stopper 36. has been done. That is, when the cap part 31 is placed over the clamp insertion part 3o and the clamp 33 is brought into contact with the upper end of the syringe 3, the clamp shaft 32 moves up and down according to the height of the clamp 33. The magnet 34 is designed to move up and down. On the other hand, a magnetoelectric transducer, for example, a Hall IC 37, is disposed inside the syringe pump body 1 facing the movement range of the magnet 34.
Magnetism from the magnet 34 is detected by this. The Hall IC 37 converts the detected magnetism into an electric signal, and sends this signal to the slider 7 described above as a control signal depending on the size of the syringe 3. The slider 7 receives this control signal and adjusts its moving distance.
Thereby, the moving distance of the piston portion 3b in the syringe 3, that is, the amount of aqueous solution delivered from the syringe 3 is adjusted. In addition, 38 is Hall IC3
A substrate 7 is held, and 39 is a substrate holder that fixes this substrate 38.

The upper case la is further provided with an operating section 10, which includes a start switch ti, a start lamp lla, a stop switch 12. Stop lamp 12a, fast forward switch 13. Fast forward lamp 13a.

Buzzer stop switch 14. W reward pump 15° injection amount display section 16. Injection amount setting switch 17. A syringe indicator lamp 18 and a power indicator lamp 19 are provided.

FIG. 5 is a longitudinal sectional view of the syringe pump main body taken along line V-V in FIG. 4. A drive motor 20 is installed inside the upper case 2a. A motor rotation detection section 21 is provided near the drive motor 20.
Control of the rotational speed of 0 is performed. The shaft of the drive motor 20 is connected to a feed screw (not shown), which is further connected to a block portion 23 via a feed nut 22. This block portion 23 is movable along the guide shaft, and the slider 7 is interlocked with this block portion 23. The slider 7 and the block part 23 are connected to the pipe shaft 24
are connected by. That is, the driving force of the drive motor 20 is transmitted to the block portion 23 via the feed screw and the feed nut 22, and further to the slider 7 via the vibe shaft 24. A clutch shaft 25 is connected to the feed nut 22, and the clutch shaft 25 is connected to a clutch 27 provided within a clutch box 26.

6 and 7 show the sealing structure of the joint between the upper case 2a and the lower case 2b. After fitting the O-ring 40 into the upper case groove provided in the upper case 2a, 2a and the lower case 2b are joined to form a syringe pump body l. By fitting this O-ring 40, it is possible to prevent unnecessary water or aqueous solution from entering the inside of the syringe pump main body 1 from the outside through the joint between the upper case 2a and the lower case 2b.

Further, as shown in FIG. 8, a warp prevention rib 41 is provided on a part of the upper case 2a. This is upper case 2
When fitting the upper case 2a and the lower case 2b, the upper case 2a may warp, making it difficult to join the upper case 2a and the lower case 2b. This is to prevent the occurrence of warping, since the joint with the case 2b may become misaligned and unnecessary water or aqueous solution may enter from there.

FIG. 9 shows a cross-sectional structure of the syringe pump function display panel section. An upper case groove 42 is provided in the upper case 2a, a silicone adhesive is applied to the groove 42, and a panel keyboard 43 is adhered to the upper case 2a. This is because the upper case 2a has a light emitting diode (LE).
Since the hole is provided so that D) can be seen, by firmly adhering the panel keyboard 43 to the upper case 2a, unnecessary water and aqueous solution are prevented from entering the inside of the syringe pump through the hole. .

FIG. 1O shows the installation structure of the buzzer mechanism. That is, a buzzer mechanism 44 is installed in the upper case 2a so that the sound of the buzzer can be clearly heard, a hole 45 is provided in the upper case 2a opposite to the installation position, and a panel keyboard 43 is further glued to the upper part of the hole 45. This prevents unnecessary water and aqueous solution from entering through the hole 45 and affecting the buzzer.

11 and 12 show the structure of the power switch display panel section. Silicone adhesive is applied to the power switch section on the side surface of the lower case 2b, and the panel keyboard 46
is firmly attached. This prevents unnecessary water and aqueous solution from entering the inside of the syringe pump from the grounded portion of the lower case 2b and the power switch 47.

Moreover, FIG. 13 shows the cross-sectional structure of the inlet part. In order to join the lower case 2b and the 2P inlet 48, a screw 50 is screwed into the insert part 49 to join the lower case 2b and the 2P inlet 48. ing. Here, an O-ring 51 is interposed at the joint between the lower case 2b and the 2P inlet 48 to prevent unnecessary water and aqueous solution from entering the inside of the syringe pump from the joint.

Next, the operation of the syringe pump of this embodiment configured as described above will be explained. First, the syringe 3 containing an aqueous solution is placed in the syringe mounting groove 5 of the syringe holding part 4, the flange part 3a of the syringe 3 is fitted into the engagement groove 6, and the piston part 3b of the syringe 3 is inserted into the slider 7. The syringe 3 is fixed to the syringe pump by engaging with the provided engaging part 8, and after adjusting the flow rate of the aqueous solution sent to the patient, the clamp part 9 is attached to the clamp insertion part 30 and the clamp 33 is attached to the syringe 3. Hold the syringe 3 from above to secure it. The magnet 34 moves up and down together with the clamp shaft 32 according to the size of the syringe 3, and the magnetism from the magnet 34 is detected by the Hall IC 37 on the syringe pump body 1 side.
After this detected magnetism is converted into an electric signal, it is sent to the slider 7 as a control signal, thereby determining the moving distance of the slider 7, that is, the amount of aqueous solution delivered.

After that, when the drive motor 20 is rotated, the driving force is applied to the feed screw, feed nut 22. The information is transmitted to the slider 7 via the block part 23 and the pipe shaft 24, and the movement of the slider 7 causes the piston part 3b of the syringe 3 to move forward, whereby a constant flow of aqueous solution is delivered from the syringe 3 to the patient via the tube at a constant time. is sent.

In the syringe pump of this embodiment driven in this manner, the slider control mechanism that sends a control signal to the slider 7 is composed of the magnet 34 and the Hall IC 37, and the m-stone 34 is inserted into the inside of the clamp insertion portion 30 or the hole. IC37
are arranged inside the syringe pump main body l, so the housing 30 of the clamp insertion part 30 is connected between the two.
Therefore, even if unnecessary water or aqueous solution accumulates inside the clamp insertion part 30a, it will not enter the inside of the syringe pump body 1, thus preventing the occurrence of various troubles as described above. can do.

Furthermore, since the sensor is a magnetic sensor, it is easily influenced by external magnetism, so in order to prevent this,
It is preferable to arrange a magnetic shielding plate on the back surface of the clamp insertion part 30 and to provide some space between the clamp insertion part 3o and the syringe pump body.

Although the present invention has been described above with reference to Examples, the present invention is not limited to the above-mentioned Examples, and can be modified in various ways without departing from the gist thereof.

[Effects of the Invention] As explained above, according to the syringe pump according to the present invention, the magnetic generating body constituting the slider control mechanism is provided inside the clamp insertion portion, and the magnetic generating body is provided inside the clamp insertion portion, and a magnetic electromagnetic body is provided for detecting the magnetism from the magnetic generating body. Since the conversion element is provided inside the syringe pump body, the housing between the clamp insertion part and the syringe pump body can be sealed, thus preventing unnecessary water and aqueous solution from entering the syringe pump body from the clamp insertion part. It is possible to prevent the intrusion of foreign substances, and the occurrence of various harmful effects can be prevented.

Further, by providing a magnetic shielding plate on the back surface of the clamp insertion portion and providing a space between the clamp insertion portion and the syringe pump body, it is possible to prevent external influences on the magnetic sensor.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view showing a clamp portion of a syringe pump according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the same, and FIG.
The figure is a perspective view of the entire syringe pump main body, Figure 4 is a plan view of the syringe pump, and Figure 5 is a V-V of Figure 4.
6 and 7 show the joint structure between the upper case and the lower case, FIG. 6 is a back view of the upper case, FIG. 7 is a sectional view of the joint, and FIG. The figure is a sectional view showing the structure of the rib part of the upper case, Fig. 9 is a sectional view of the function display panel part, Fig. 10 is a sectional view of the buzzer installation part, and Figs. 11 and 12 are the power switch display panel. 11 is a side view, FIG. 12 is a cross-sectional view, and FIG. 13 is a cross-sectional view of the inlet portion. l...Syringe pump body, 2a...-Lower case, 4...Syringe holding part, 5...Syringe placement groove, 7...Slider, 30...-Clamp insertion part, 32... Clamp shaft, 34...Magnet, 37...Hall IC 2a--Upper case 3...Syringe 6...Engaging groove 9...Clamp part 31...Cap part 33...Clamp 35... Compression coil spring Fig. 2 Fig. 4 Fig. 5 Fig. 9 Fig. 10 Fig. 1I Fig. 12 Fig. 13

Claims (3)

[Claims] (1) A syringe pump that pumps out a constant flow rate of an aqueous solution over a certain period of time from a syringe containing an aqueous solution, in which a syringe pump body, a syringe mounting groove provided in the syringe pump body, and a flange portion of the syringe are engaged with each other. A syringe holding part consisting of an engaging groove that fits together, a clamp insertion part provided on the syringe pump body, and a syringe attached to the clamp insertion part and held by the syringe holding part is fixed from above. a clamp part that moves up and down depending on the size of the syringe; a magnetic generator that is disposed within the clamp insertion part and moves up and down as the clamp part moves up and down; a slider control mechanism comprising a magnetoelectric conversion element that detects magnetism from a magnetic generator and outputs a control signal according to the size of the syringe; and a slider control mechanism that engages with a piston portion of the syringe and receives control from the control mechanism. A syringe pump comprising: a slider that pushes the piston part forward in response to a signal. (2) The syringe pump according to claim 1 or 2, further comprising a magnetic shielding plate provided on the back surface of the clamp insertion portion. (3) The syringe pump according to claim 1 or 2, wherein a space is provided between the clamp insertion portion and the syringe pump main body.