JPH0519932U - Indwelling pressure detector - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide an indwelling type pressure detection device capable of stably and highly accurately measuring the pressure of body fluid such as blood as the sum of dynamic pressure and static pressure in a state of being placed in the body. .. [Structure] The pressure detecting device 20 includes an insulating thin tube 22,
A sensor assembly 30 arranged at a position axially separated from the tip of the thin tube 22 by a predetermined distance, and a gel filled in a space from the tip of the thin tube 22 to the sensor assembly 30 and having an insulating property and a low viscoelasticity. Pressure transmission medium 40. Then, the sensor assembly 30
Is formed on the base 32 and an insulating base 32 fixed in the thin tube 22, a pressure detection element 34 fixed to the base 32 and including a pressure-sensitive diaphragm 52 arranged at right angles to the axial direction, and the base 32. The pressure detecting element 34 has an atmosphere communication hole 36 for introducing atmospheric pressure.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 INDUSTRIAL APPLICABILITY The present invention is used for measuring in-vivo pressure used in the medical field, such as blood pressure, intracranial pressure, esophageal pressure, bladder pressure, urethral pressure and other pressures, and has a sufficiently small size to be directly inserted into a blood vessel or the like. The present invention relates to an indwelling pressure detection device.

[0002]

[Prior Art]

 BACKGROUND ART Pressures such as blood pressure are measured to diagnose and treat physiological conditions of the living body. Taking the blood pressure measurement of a living body as an example, there are an indirect measurement method and a direct measurement method.

The former indirect measurement method has been conventionally performed by using a pressure cuff and an auscultation method together, and recently, it has been widely used as a home blood pressure monitor. Although this method has the advantage of not causing pain or burden to the patient, it has problems in terms of measurement accuracy and continuous monitoring.

On the other hand, in the direct measurement method, a device called “external blood pressure monitor” has been used for a long time. This measuring device inserts a catheter into the measurement site, uses a liquid (for example, physiological saline) filled in the catheter as a pressure transmitting medium, transmits pressure to a pressure converter connected to the outside of the body, and electrically It is a method to detect. However, this method causes a large error due to the compliance of the diaphragm of the catheter and the pressure transducer, the movement of the liquid column in the catheter, and the viscosity of the liquid, and when the air bubbles enter the catheter, the error is superposed. , Accurate measurement was difficult.

In order to solve these drawbacks, an attempt has been made to set a pressure transducer at the tip of the catheter, and a measuring device as shown below has been proposed. The measuring device shown in FIG. 13 has a structure in which the periphery of the silicon pressure element 1 is firmly fixed to the quartz tube 3 with the epoxy resin 2. In this device, strain due to thermal stress generated at the joint between the epoxy resin 2 and the silicon pressure element 1 causes an unbalanced voltage called heat output, which impairs performance. Further, in the measuring device shown in FIG. 14, the silicon pressure element 4 is bonded to the end portion of the polyvinyl chloride tube 6 by the silicon resin 5. With this device, the adhesion with the silicone resin 5 relaxes the thermal strain, so the heat output can be made small, but the structural mechanical strength is insufficient, so it is susceptible to external mechanical strain and stable measurement is difficult. is there. In order to solve the above-mentioned two drawbacks of the conventional apparatus, there is an apparatus described in Japanese Patent Publication No. 59-21495 shown in FIG. This is called a lateral pressure type and is a device that measures only static pressure. In this device, a pressure receiving hole 14 is provided on a side surface at a predetermined distance from the distal end of a catheter 10, and a silicon pressure element 7 has an atmosphere introducing hole 8 at a position facing the pressure receiving hole 14 on a support 9 having a silicon rubber. It is softly attached by a flexible adhesive such as. The upper surface of the silicon pressure element 7 is kept airtight by the silicon resin 11.

In this structure, since the silicon pressure element 7 is only supported by the support base 9 by soft adhesion, the heat output due to thermal strain is relaxed. Further, since the silicon pressure element 7 is fixed inside the catheter 10, it has a strong structure against mechanical strain from the outside.

However, there is a drawback that the performance is deteriorated due to the influence of the silicon resin 11 on the pressure receiving portion. That is, since the pressure transmissibility of the silicone resin 11 is low, problems such as deterioration or variation in sensitivity, non-linearity, hysteresis, and generation of heat output are likely to occur.

[0008] These problems largely depend on the thickness of the layer of the silicone resin 11, and when the thickness of the silicone resin 11 changes, the changes in these values become remarkable, so that the measurement result is highly reliable and stable. Is difficult to obtain.

With the diversification of blood pressure measurement tests, there is an increasing demand for not only static pressure but also the sum of static pressure and dynamic pressure, and information on only dynamic pressure.

[0010]

[The purpose of the device]

 The present invention solves the above-mentioned problems of the prior art, and its purpose is to stably and accurately measure the pressure of body fluid such as blood as the sum of dynamic pressure and static pressure in a state of being left inside the body. An object of the present invention is to provide an indwelling pressure detection device that can be used.

[0011]

[Device configuration]

 In order to achieve the above object, an indwelling type pressure detecting device of the present invention is arranged with an insulating thin tube and a position axially separated from the tip of the thin tube by a predetermined distance. A sensor assembly having a. An insulative base fixed within the capillary, b. A pressure sensing element fixed to the base and including a pressure sensitive diaphragm disposed at right angles to the axial direction; and c. An air communication hole formed in the base portion for introducing atmospheric pressure into the pressure detecting element, filled in a void portion from the tip of the thin tube to the pressure-sensitive diaphragm of the pressure detecting element, and having an insulating and low viscosity. And a gel-like pressure transmission medium having elasticity.

[0012]

[Action]

 In the present invention, by inserting the tip of the pressure detecting device into the measurement site in the living body, pressure such as blood pressure in the living body is applied to the pressure sensitive diaphragm via the gel pressure transmission medium and output as an electric signal. To be done. At this time, since the pressure-sensitive diaphragm is installed vertically to the flow of the liquid to be detected, its pressure can be measured as the sum of static pressure and dynamic pressure.

Further, in the apparatus having the above-mentioned configuration, by interposing a specific gel-like pressure transmission medium between the pressure-sensitive diaphragm constituting the pressure detection element and the liquid to be detected, the electrical insulation between the two is ensured. Furthermore, it prevents foreign matter such as fragments of the pressure-sensitive diaphragm from entering the living body. The characteristic feature of the gel-type pressure transmission medium is that it has extremely low elasticity, so that the pressure of the liquid to be detected can be transmitted to the pressure-sensitive diaphragm with almost no pressure loss, and is therefore highly accurate and stable. It is possible to detect various pressures.

[0014]

[Explanation of other ideas]

 (Second Invention) The pressure sensor indwelling in the body according to the second invention is a medium holding unit for preventing the gel pressure transmitting medium from dropping from the tip of the thin tube in at least one of the thin tube and the sensor assembly. Is provided.

According to this device, by providing the medium holding portion, it is possible to reliably prevent the gel-like pressure transmission medium in the thin tube from dropping into the living body, so that the safety to the living body is ensured. can do.

(Third Invention) In the indwelling pressure detection device according to the third invention, a distance L (filling length of a gel-like pressure transmission medium) from the tip of the thin tube to the pressure-sensitive diaphragm of the pressure detection element, The ratio L / D to the diameter (inner diameter) D of the thin tube is 1 to 4, and the ratio S / a of the cross-sectional area S of the thin tube to the area a of the pressure-sensitive diaphragm is 7 to 14. And

By setting L / D and S / a to this value, the thickness and the thickness of the gel pressure transmitting medium are set sufficiently large while ensuring the accuracy and stability in pressure detection within a predetermined high range. Therefore, the function as the protective layer can be surely exhibited.

(Fourth Invention) The indwelling pressure detection device according to the fourth invention is characterized in that the gel communication is also filled in the atmosphere communication hole.

According to this device, since the gel pressure transmitting medium is filled on both sides of the pressure-sensitive diaphragm, the influence of elasticity of the gel pressure transmitting medium is canceled and more accurate measurement is possible. is there.

(Fifth Invention) In the indwelling pressure detection device according to the fifth invention, a pressure receiving hole is provided on a side surface of the thin tube, and the sensor assembly (first sensor assembly) is provided at a position facing the pressure receiving hole. A second sensor assembly having a pressure-sensitive diaphragm similar to the above is provided in the axial direction, the gel pressure transmission medium is filled in the void portion extending from the pressure receiving hole to the second sensor assembly, and the pressure receiving hole can be slid. It is characterized in that it can be opened and closed with a simple lid member.

According to this invention, by opening the pressure receiving hole, only the static pressure of the liquid to be detected can be measured by the second sensor assembly. Therefore, only the dynamic pressure can be accurately measured by subtracting the pressure value of the second sensor assembly from the pressure value of the first sensor assembly.

Further, in this device, the sum of the dynamic pressure and the static pressure can be measured by closing the pressure receiving hole. Therefore, by opening and closing the pressure receiving hole, only the dynamic pressure can be measured, or It is possible to selectively measure the sum of the dynamic pressure and the static pressure.

[0023]

【Example】

 Next, the present invention will be described in more detail by way of examples.

(First Embodiment) FIG. 1 is a sectional explanatory view showing a main part of an indwelling type pressure detecting device 20 according to a first embodiment of the present invention. The detection device 20 includes a thin tube 22, a sensor assembly 30 arranged in the thin tube 22 at a position axially separated from the tip of the thin tube 22 by a predetermined distance, and a sensor assembly 30 from the tip of the thin tube 22. Up to the gel-like pressure transmission medium 40 filled in the space.

The thin tube 22 is preferably an electrically insulating and antithrombogenic material, and for example, segmented polyurethane or polyvinyl chloride hydrophilically treated with plasma can be preferably used.

As the gel pressure transmission medium 40, silicon gel having a high electric insulating property and a small elastic modulus is suitable. This silicone gel has an elastic modulus as small as about 1/1000 as compared with the conventionally used silicone resin, and specifically, an elastic modulus of 1 to 30 × 10 ⁻⁴ kg / mm ² is preferable.

As shown in the enlarged view of FIGS. 2 and 3, the sensor assembly 30 includes a base 32, a pressure detection element 34 provided at the tip of the base 32, and an electrical connection to the pressure detection element 34. And a lead wire 38 connected to.

The base portion 32 has a cylindrical shape as a whole, and a cylindrical portion 32 a for mounting the pressure detection element 34 is formed at the tip portion thereof. Further, the base portion 32 has an atmosphere communication hole 36 formed along the central axis thereof. A plurality of lead wires 38 (five in the case of this embodiment) are provided around the atmosphere communication hole 36. The lead wire 38 is attached with its tip 38a slightly protruding from the end face of the base 32.

The base portion 32 is made of ceramics, has electrical insulation and sufficient rigidity, and has a sufficient rigidity with respect to the pressure detection element 34 mounted in the state surrounded by the tubular portion 32a. Care is taken not to give distortion due to external force.

As shown in FIGS. 4 and 5, the pressure detecting element 34 is composed of a silicon substrate 50 having a pressure sensitive diaphragm 52 in the central portion. Such a pressure-sensitive diaphragm 52 can be formed by anisotropically etching the central portion of a thin silicon substrate from the back surface.

The pressure-sensitive diaphragm 52 is formed with four strain gauges 54a to 54d. The strain gauges 54a to 54d are formed by a diffusion technique or an ion implantation technique. Further, five aluminum pads 56a to 56e are formed so as to surround the pressure-sensitive diaphragm 52, and solder terminals 58a to 58e are formed on the aluminum pads 56a to 56e, respectively. The solder terminals 58a to 58e can be formed, for example, by sequentially depositing chromium, nickel, and gold to form electrodes by a lift-off method, and fusing the solder to the electrodes in molten solder. Further, the aluminum pads 56a to 56e and the strain gauges 54a to 54d are electrically connected by aluminum in a predetermined pattern. A bridge circuit is configured by the above circuits, and an electric signal proportional to the pressure applied to the pressure sensitive diaphragm 52 can be taken out. In addition, since the circuit on the silicon substrate 50 described above can be formed in wafer units, the productivity is good.

Further, on the back surface side of the silicon substrate 50, a flange-shaped medium holding portion 60 protruding toward the center of the hole 64 formed by etching is formed. In this medium holding unit 60, a polysilicon film 62 is formed between the silicon substrate 50 and a silicon nitride film (60) which constitutes an etching mask, and the holes of the polysilicon film 62 are formed by the holes of the silicon nitride film 60. By forming it large, the opening region of the hole 64 is made larger than the opening portion of the silicon nitride film 60, and as a result, the silicon nitride film 60 is projected toward the center. Further, as shown in FIG. 6, the pressure detecting element 34 is formed with a silicon plate 66 having an opening portion having a diameter smaller than the opening portion diameter of the hole 64 in advance. It can also be formed by joining to.

When forming the sensor assembly 30 by joining the base portion 32 and the pressure detecting element 34, as shown in FIG. 3, the tip portion 38 a of the lead wire 38 of the base portion 32 and the pressure detecting element 34 are connected. The solder terminals 58 (58a to 58e) are aligned and temporarily fixed by flux. Then, the heat treatment with infrared rays or the like melts the flux and the solder, and the surface tension generated at that time concentrates the solder on the tip end portion 38a of the lead wire 38, completing the connection between the two.

In this embodiment, the ratio L / D of the distance L from the tip of the thin tube 22 to the pressure sensitive diaphragm 52 of the pressure detecting element 34 and the diameter D of the thin tube 22 is 1 to 4. The ratio S / a of the cross-sectional area S of the thin tube 22 and the area a of the pressure-sensitive diaphragm 52 is preferably set to 7-14. By setting the ratios L / D and S / a in the specific numerical ranges in this way, the effect of the gel pressure transmission medium 40 on the sensitivity of the pressure detection element 34 can be suppressed to a certain value or less, and highly accurate and stable. The pressure can be measured in a reliable manner, and the function as a protective film of the gel pressure transmission medium 40, that is, the function of ensuring electrical insulation and preventing the adverse effect on the human body due to damage of the pressure-sensitive diaphragm 52 and the like is ensured. Can be achieved.

When the ratio L / D exceeds 4 and S / a becomes less than 7, a shearing force acts on the peripheral portion of the gel pressure transmitting medium 40 to absorb the pressure, resulting in the gel pressure transmitting. Compared to the case where the pressure detecting element 34 is used alone without using a medium, the sensitivity is lowered by about 2 to 3%. Further, if the ratio L / D is less than 1, the electric insulation of the gel pressure transmission medium 40 becomes insufficient.

Further, when the ratio L / D exceeds 4 and S / a exceeds 14, the elastic force of the gel-like pressure transmission medium 40 decreases and thermal strain (thermal stress) due to temperature change causes pressure detection element. 34 is transmitted to the pressure-sensitive diaphragm 52. As a result, the heat output is increased by about 0.2 mmHg / ° C. as compared with the case of the pressure detecting element alone, which causes a problem that the characteristics are deteriorated.

Next, as an application example of the first embodiment, an example of the size of each component is shown below.

Inner diameter D of thin tube 22; 0.8 mm Diameter of base 32; 0.8 mm, length; 2 mm Diameter of lead wire 38; 50 μm, length; 7 mm, length of tip portion 38 a; 50 μm Pressure detection element Diameter of 34; 0.5 mm, thickness; 0.15 mm Diameter of pressure-sensitive diaphragm 52; 0.2 mm, thickness; 6 μm Diameter of atmosphere communication hole 36; 100 μmAction  Next, the operation of this embodiment will be described.

In the pressure detection device 20 of the present embodiment, when measuring the pressure, the pressure-sensitive diaphragm 52 is perpendicular to the axial direction (flow direction) of the fluid to be detected in the fluid to be detected in the living body. Is set. By doing so, the sum of the static pressure and the dynamic pressure of the fluid to be detected, that is, the total pressure can be measured.

By interposing the gel-like pressure transmission medium 40 between the pressure-sensitive diaphragm 52 and the liquid to be detected, the electric insulation between the two is ensured, and the pressure-sensitive diaphragm 52 and the like are separated by some cause. It is possible to prevent foreign matter that has a bad effect on the living body, such as broken pieces and a part of the substance forming the sensor assembly 30 when broken, from entering the liquid to be detected.

Since the gel pressure transmitting medium 40 has an extremely small elastic modulus, the pressure of the liquid to be detected can be transmitted in a state where the pressure loss is extremely small, and highly accurate and stable pressure detection can be performed. It can be carried out. Further, changes in pressure loss and the like due to changes in the thickness of the gel pressure transmission medium 40 are small, and therefore it is not necessary to strictly define the thickness unlike the conventional rubber-like protective film, so the pressure detection device 20 The positioning of the sensor assembly 30 is facilitated during the assembly of FIG.

In order to make the above point clearer, it is shown below by measured values that the performance of the pressure detection device differs depending on the difference of the pressure transmission medium.

For example, in the conventional apparatus shown in FIG. 15, when the diameter of the pressure sensitive diaphragm of the silicon pressure element 7 is 0.5 mm, when the thickness of the silicon resin 11 changes from 0.1 mm to 0.2 mm. , The sensitivity is reduced by 2-5%. Also, at this time, the heat output increases by 3 to 6%. Further, regarding the zero-point drift, the thickness of the silicon resin is 0. When the thickness is 1 mm, there is not much influence, but when the thickness is 0.2 mm, it is not stable even after 1 hour, and quick and reliable measurement is difficult.

On the other hand, in the present embodiment, even if the thickness of the gel pressure transmitting medium 40 is 10 mm, the decrease in sensitivity is 0.5% or less as compared with the case where the thickness is 0.1 mm. As a result, the heat output has risen to less than 1%. In addition, the zero-point drift can be stabilized within a few minutes, enabling quick and reliable measurement.

Further, in the present embodiment, the pressure detecting element 34 has a flange-shaped medium holding portion 60 projecting in the axial direction, and the medium holding portion 60 has the gel-like pressure transmission medium 40. Since the gel pressure transmitting medium 40 is in a state of being bitten into the layer, the gel-like pressure transmitting medium 40 can be reliably prevented from coming off, and safety to the living body is ensured.

Further, in the present embodiment, the base end 32 of the sensor assembly 30 is formed into a tubular shape at the front end side, and the pressure detecting element 34 is fixed in the tubular portion 32a while being inserted therein. Therefore, the strain due to the force applied from the outside is not applied to the pressure detection element 34. As a result, the change of the zero point in the process of inserting the tip of the pressure detecting device 20 to a predetermined position inside the blood vessel can be made extremely small, and stable measurement can be performed.

(Second Embodiment) FIG. 7 is a sectional explanatory view showing a main part of a pressure detecting device 20 according to a second embodiment of the present invention. The same members as those in the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

The present embodiment differs from the first embodiment in that the gel-like pressure transmission medium 40 is filled on both sides of the pressure-sensitive diaphragm 52. That is, in the first embodiment, only one of the pressure-sensitive diaphragms 34 (the tip side of the thin tube 22) is filled with the gel pressure transmitting medium 40, but in the present embodiment, in addition to this, The air communication hole 36 on the opposite side is also filled with a similar gel pressure transmission medium 42.

By thus filling both sides of the pressure-sensitive diaphragm 52 with the gel pressure-transmitting medium 40, the elastic effects of the pressure-transmitting medium are mutually canceled, and the gel-like pressure transmitting medium is The effect of pressure loss due to filling can be further reduced. Furthermore, it is possible to eliminate the influence of mechanical strain caused by filling the pressure transmission medium on only one side, and it is possible to perform pressure measurement with higher accuracy.

Third Embodiment FIG. 8 is a schematic sectional view showing a third embodiment of the present invention. The same members as those of the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

In the present embodiment, the pressure receiving hole 24 is formed at a position distant from the tip of the thin tube 22 by a predetermined distance, the second sensor assembly 70 is provided at a position facing the pressure receiving hole, and the pressure receiving hole 24 is also provided. This is different from the first embodiment in that a lid member 26 is provided outside the thin tube 22.

The second sensor assembly 70 includes a base 72 made of ceramics, a pressure detecting element 74 provided on the upper surface of the base 72 and having a pressure sensitive diaphragm 74b at the center of a silicon substrate 74a, and the base 72. It is composed of an atmosphere communication hole 76 provided, and its operation is almost the same as that of the first sensor assembly 30. Further, a gel pressure transmitting medium 44 similar to the gel pressure transmitting medium 40 is filled in the void portion extending from the pressure receiving hole 24 to the pressure detecting element 74. The lid member 26 is composed of a tubular slide member attached to the outer periphery of the thin tube 22, and the pressure receiving hole 24 can be opened and closed by sliding the lid member 26 in the axial direction.

According to the present embodiment, the total pressure of the liquid to be detected (dynamic pressure + static pressure) is measured by the first sensor assembly 30 in the first embodiment. Practicality is further enhanced in that only dynamic pressure can be measured. That is, by replacing the cover member 26 and opening the pressure receiving hole 24, only the static pressure of the liquid to be detected can be measured by the second sensor assembly 74, and the first sensor assembly 30 can be measured. Only the dynamic pressure of the liquid to be detected can be obtained by subtracting the pressure value obtained by the second sensor assembly 74 from the pressure value obtained by. Then, by advancing the lid member 26 to close the pressure receiving hole 24, the same configuration as that of the first embodiment is obtained, and the total pressure of the liquid to be detected can be measured. As described above, according to this embodiment, the total pressure or the dynamic pressure can be selectively measured by operating the lid member 26.

(Other Embodiments) The present invention is not limited to the above embodiments, and various modifications can be made.

For example, FIG. 9 shows a modification of the base portion 32 that constitutes the sensor assembly 30. In this example, the base portion is composed of an outer cylinder 32b and an inner cylinder 32c, and the tip of the outer cylinder 32b is extended from the inner cylinder 32c to the outside to form a mounting region of the pressure detection element 34. According to such a double pipe structure, the base can be formed more easily than the method of forming the concave portion at the tip as in the case of the first embodiment.

10 to 12 show a modified example of the medium holding portion for preventing the gel pressure transmission medium 40 from falling off.

That is, in the configuration example shown in FIG. 10, the medium holding portion 22 a is formed by a taper that gradually increases the wall thickness of the thin tube 22 toward the tip. By gradually inclining the inner wall of the thin tube 22 toward the tip in this way, the inside of the tip of the thin tube 22 becomes a tapered state, and the gel pressure transmission medium 40 filled therein does not fall off.

In the configuration example shown in FIG. 11, the medium holding portion 22 b is formed by unevenness formed on the inner wall at the tip of the thin tube 22. In this manner, the uneven medium holding portion 22b is in a state of biting into the side surface of the gel pressure transmitting medium 40, and it is possible to prevent the drop.

In the configuration example shown in FIG. 12, the base portion of the sensor assembly 30 is composed of an outer cylinder 32b and an inner cylinder 32c as in the case shown in FIG. 9, and the tip of the outer cylinder 32b is bent further inward. With this shape, the protruding portion constitutes the medium holding portion 32d. The function of the medium holding portion 32d is similar to that of the medium holding portion 64 of the first embodiment, but its formation is easy.

[0060]

[Effect of the device]

 According to the present invention, the pressure of body fluid such as blood can be stably measured with high accuracy as the sum of dynamic pressure and static pressure in a state of being placed in the body.

[Brief description of drawings]

FIG. 1 is an explanatory sectional view showing an essential part of a first embodiment of the present invention.

2 is an enlarged cross-sectional explanatory view of the sensor assembly shown in FIG.

FIG. 3 is an exploded perspective view showing an assembled state of the sensor assembly.

FIG. 4 is a perspective explanatory view showing a configuration of a pressure detection element.

5 is an AA cross-sectional explanatory view of the pressure detection element shown in FIG.

FIG. 6 is an explanatory cross-sectional view showing another configuration example of the pressure detection element.

FIG. 7 is an explanatory sectional view showing an essential part of a second embodiment of the present invention.

FIG. 8 is an explanatory sectional view showing an essential part of a third embodiment of the present invention.

FIG. 9 is an explanatory cross-sectional view showing another configuration example of the sensor assembly of the present invention.

FIG. 10 is a cross-sectional explanatory view showing another example of the configuration of the medium holding unit of the present invention.

FIG. 11 is an explanatory cross-sectional view showing another configuration example of the medium holding unit of the present invention.

FIG. 12 is a sectional explanatory view showing another example of the structure of the medium holding unit of the present invention.

FIG. 13 is a cross-sectional explanatory view showing an example of a conventional pressure detecting device.

FIG. 14 is a cross-sectional explanatory view showing another example of the conventional pressure detecting device.

FIG. 15 is a cross-sectional explanatory view showing another example of the conventional pressure detecting device.

[Explanation of symbols]

20 pressure detection device 22 thin tube 24 pressure receiving hole 26 lid member 30 sensor assembly 32 base portion 34 pressure detection element 36 atmosphere communication hole 40, 42, 44 gel pressure transmission medium 50 silicon substrate 52 pressure sensitive diaphragm 64 medium holding portion 70 second Sensor assembly
TC006602

Claims (5)

[Scope of utility model registration request] 1. An insulative thin tube, a sensor assembly arranged at a position axially separated from the tip of the thin tube by a predetermined distance, and having the following configurations a to c: a. An insulative base fixed within the capillary, b. A pressure sensing element including a pressure sensitive diaphragm fixed to the base and arranged at right angles to the axial direction; and c. An atmosphere communication hole formed in the base portion for introducing atmospheric pressure to the pressure detection element, filled in a void portion from the tip of the thin tube to the pressure-sensitive diaphragm of the pressure detection element, and having insulating and low viscoelasticity And a gel-like pressure transmission medium having: 2. The medium holding unit according to claim 1, wherein at least one of the thin tube and the sensor assembly is provided with a medium holding portion that prevents the gel pressure transmission medium from falling off the tip of the thin tube. In-body pressure detector. 3. The ratio L / D between the distance L from the tip of the thin tube to the pressure-sensitive diaphragm of the pressure detection element and the diameter D of the thin tube according to claim 1.
4, the ratio S / a of the cross-sectional area S of the thin tube and the area a of the pressure-sensitive diaphragm is 7-14. 4. The indwelling pressure detection device according to claim 1, wherein the atmosphere communication hole is also filled with the gel pressure transmission medium. 5. The pressure receiving hole according to claim 1, wherein a pressure receiving hole is provided on a side surface of the thin tube, and a pressure sensitive diaphragm similar to the sensor assembly (first sensor assembly) is axially provided at a position facing the pressure receiving hole. A second sensor assembly is provided, a gel pressure transmission medium is filled in a void portion extending from the pressure receiving hole to the second sensor assembly, and the pressure receiving hole can be opened and closed by a slidable lid member. In-body pressure detection device.