KR101696693B1 - Myofascial pressure measuring apparatus - Google Patents

Abstract

Disclosed is a myofascial pressure measuring apparatus. The myofascial pressure measuring apparatus of the present invention includes: a housing; a cover coupled to the housing and connected to a needle part; a holder part connected to the cover and disposed inside the housing; a supply channel part disposed in the holder part to be connected to the needle part; a syringe part disposed in the holder part and connected to the supply channel part to supply a pressure measuring solution to the needle part; a pressure measuring part for measuring the pressure of the pressure measurement solution supplied to the supply channel part; a pressure driving part connected to the syringe part; and an operation part connected to the pressure driving part and rotatably installed in the housing to drive the pressure driving part. So, a myofascial pressure can be accurately measured.

Description

[0001] MYOFASCIAL PRESSURE MEASURING APPARATUS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring an intrafascial pressure, and more particularly, to an apparatus for measuring an intrafascial pressure capable of accurately measuring an intrafascial pressure.

In general, compartment syndrome is a disease in which the pressure of the compartment (the group of muscles surrounded by the inelastic fascia) rises above the pressure in the capillary. Compartment syndrome causes blood circulation limitation or circulation decrease within the compartment. People with compartment syndrome do not normally inflate the fascia, so bleeding or edema resulting from trauma or damage to the body increases pressure within the compartment. As circulation of blood and the like is continuously restricted within the compartment, tissues such as muscles and nerves can be necrotized. Necrosis of the tissue may result in severing limbs or loss of life.

Normal pressure within the fascia is less than 20 mmHg, and pressure within the fascia is 20-30 mmHg, which increases the likelihood of compartment syndrome. If the pressure in the fascia exceeds 30 mmHg, a diagnosis of compartment syndrome may be obtained.

In order to diagnose the compartment syndrome, the needle is infiltrated into the fascia and then the physiological saline is injected to measure the pressure inside the fascia. However, it is difficult to accurately diagnose the compartment syndrome if the input amount of the saline solution is not accurate. It was also difficult to diagnose compartment syndrome early in compartment syndrome.

BACKGROUND OF THE INVENTION [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2013-0140616 (published on Dec. 24, 201, entitled " System and Method for Monitoring Compartment Syndrome).

SUMMARY OF THE INVENTION It is an object of the present invention to provide an intrafascial pressure measuring device capable of accurately measuring a pressure in a fascia.

An apparatus for measuring pressure in a fascia according to the present invention includes: a housing; A cover coupled to the housing and to which a needle portion is connected; A holder connected to the cover and disposed inside the housing; A supply channel portion disposed in the holder portion to be connected to the needle portion; A silent portion disposed in the holder portion and connected to the supply channel portion to supply a pressure measuring solution to the needle portion; A pressure measuring unit disposed in the holder unit and measuring a pressure of the pressure measuring solution supplied to the supply channel unit; A pressure driver connected to the syringe; And an operation unit connected to the pressure driving unit and rotatably installed in the housing to drive the pressure driving unit.

Wherein the pressure driver includes: a first gear portion mounted to rotate by the operation portion; A rotating rod portion connected to a rotating shaft of the first gear portion and supported by the housing; A second gear portion fixed to the rotary rod portion; A third gear portion which meshes with the second gear portion and is moved along the longitudinal direction of the rotary rod portion together with the second gear portion when the second gear portion rotates; And a moving rod portion that is axially coupled to the third gear portion and presses the syringe portion when the third gear portion rotates to discharge the pressure measuring liquid from the syringe portion.

The third gear portion is fixed to the moving rod portion, and the moving thread portion of the moving rod portion is screwed to the supporter portion to be moved together with the third gear portion. have.

Wherein the operating portion includes: an operating wheel portion rotatably installed in the housing; And an actuator unit formed on an inner surface of the operation wheel unit to engage with the first gear unit.

The cover may be detachably installed on one side of the housing, and the holder may be fixed to the cover so as to be separated from the housing together with the cover.

The holder portion may include an insertion portion formed to insert the syringe portion, and a receiving portion to receive the pressure measurement portion.

Wherein the pressure measuring device comprises: a light emitting unit disposed on the cover; A power supply unit disposed in the housing and supplying power to the light emitting unit; And a controller for controlling the power supply unit such that light is emitted from the light emitting unit when the pressure measured by the pressure measuring unit is equal to or higher than a set pressure.

The control unit may control the light emitting unit to emit light of a different color from that of the light emitting unit when the pressure measured by the pressure measuring unit is less than the set pressure.

The fascia pressure measuring apparatus may further include a display unit disposed in the housing and displaying a pressure measured by the pressure measuring unit.

According to the present invention, since the supply of the pressure measurement liquid is controlled in the syringe portion by rotating the operation portion, the amount of the pressure measurement liquid injected into the inside of the fascia can be accurately controlled.

Further, according to the present invention, since the amount of the pressure measurement liquid injected into the inside of the fascia is accurately controlled, the pressure in the fascia can be accurately measured.

1 is a perspective view illustrating an apparatus for measuring pressure in a fascia according to an embodiment of the present invention.
2 is a plan view showing an apparatus for measuring pressure in the fascia according to an embodiment of the present invention.
3 is an exploded perspective view showing an apparatus for measuring pressure in the fascia according to an embodiment of the present invention.
4 is a perspective view illustrating an operation unit of the apparatus for measuring pressure in the fascia according to an embodiment of the present invention.
FIG. 5 is a perspective view illustrating an apparatus for measuring pressure within a fascia according to an exemplary embodiment of the present invention, in which a power supply unit is installed inside a housing.
6 is a cross-sectional view illustrating an apparatus for measuring pressure in the fascia according to an embodiment of the present invention.

Hereinafter, an embodiment of an apparatus for measuring pressure within a fascia according to the present invention will be described with reference to the accompanying drawings. In the course of describing the apparatus for measuring pressure in the fascia, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view illustrating an apparatus for measuring pressure within a fascia according to an embodiment of the present invention, FIG. 2 is a plan view illustrating an apparatus for measuring pressure within a fascia according to an embodiment of the present invention, and FIG. 4 is a perspective view illustrating an operation unit of an apparatus for measuring pressure in a fascia according to an embodiment of the present invention. FIG. 5 is a perspective view of an embodiment of the present invention FIG. 6 is a cross-sectional view illustrating an apparatus for measuring pressure within a fascia according to an exemplary embodiment of the present invention. Referring to FIG.

1 to 6, an apparatus 100 for measuring pressure within a fascia according to an exemplary embodiment of the present invention includes a housing 110, a cover 120, a holder 130, a supply channel 135, A pressure measuring unit 150, a pressure driving unit 160, and an operating unit 170. The pressure measuring unit 150 includes a pressing unit 140, a pressure measuring unit 150,

The housing 110 may be formed in a cylindrical or polygonal shape with open sides. The housing 110 may be formed of various materials such as stainless steel, synthetic resin, and the like.

A stepped portion 111 is formed on one side of the housing 110 so that the operating portion 170 is rotatably coupled. The cutout portion 112 is formed in the stepped portion 111 such that a part of the first gear portion 161 of the pressure drive portion 160 is disposed. The first gear portion 161 passes through the cutout portion 112 and is engaged with the operation unit 170 of the operation portion 170.

The cover 120 is coupled to one side of the housing 110. A needle portion 124 is connected to the cover 120. At this time, a nozzle part 123 is formed to protrude in the center of the cover 120 so that the needle part 124 is engaged.

The holder portion 130 is connected to the cover 120 and disposed inside the housing 110. The holder 130 may be formed in various shapes such as a rectangular parallelepiped. The holder 130 is connected to the cover 120 so that when the cover 120 is coupled to one side of the housing 110, the holder 130 is disposed inside the housing 110. Accordingly, the cover 120 and the holder 130 can be installed in the housing 110 at the same time.

The cover 120 is detachably installed on one side of the housing 110 and the holder 130 is fixed to the cover 120 so as to be separated from the housing 110 together with the cover 120. A threaded portion (not shown) is formed on the periphery of the cover 120 so as to be screwed to the housing 110. The holder 120 is fixed to the cover 120 and the cover 120 is detachably installed at one side of the housing 110 so that the cover 120 and the holder 130 are installed simultaneously in the housing 110 Or separated.

The holder 130 has an insertion part 132 formed to insert the syringe part 140 and a receiving part 133 to accommodate the pressure measuring part 150. The needle portion 124, the pressure measuring portion 150 and the syringe portion 140 can be easily replaced at once because the holder portion 130 is provided with the syringe portion 140 and the pressure measuring portion 150. [ Further, since the needle portion 124, the pressure measuring portion 150, and the syringe portion 140 used as consumables are replaced, the housing 110 and the like can be used again. In addition, since the needle portion 124, the pressure measuring portion 150, and the syringe portion 140 through which the pressure measuring solution flows can be exchanged at once, the secondary infection path can be originally blocked. Also, consumables can be easily separated and discarded.

The supply channel portion 135 is disposed in the holder portion 130 to be connected to the needle portion 124. The supply channel portion 135 is a flow passage through which the pressure measurement liquid flows. The pressure measurement solution is physiological saline which is harmless to the human body.

A syringe 140 is disposed in the holder portion 130 and is connected to the supply channel portion 135 to supply a pressure measuring solution to the needle portion 124. The syringe unit 140 includes a syringe body 141 in which the pressure measuring solution is received and a pusher 143 installed in the syringe body 141 to pressurize the pressure measurement liquid. A discharge portion (not shown) is formed at one end of the syringe body 141 and an other portion of the syringe body 141 is opened to insert the pusher portion 143. The pusher portion 143 includes a pressure sealing portion (not shown) which is in close contact with the inner surface of the syringe body 141. As the pusher portion 143 is pressed, the pressure measuring liquid is discharged from the discharging portion of the syringe body 141.

The pressure measuring unit 150 is disposed in the holder unit 130 and measures the pressure of the pressure measuring solution supplied to the supply channel unit 135. The pressure measuring section 150 includes a pressure chamber section 151, a membrane 153 and a pressure sensor section 155.

The pressure chamber portion 151 is connected to the supply channel portion 135 and expanded as the pressure measurement liquid is supplied. The supply channel portion 135 includes a first supply channel portion 135a connecting the pressure chamber portion 151 and the discharging portion of the syringe body 141 and a second supply channel portion 135b connecting the nozzle portion 123 and the pressure chamber portion 151 of the cover 120 And a second supply channel portion 135b connecting the first supply channel portion 135a and the second supply channel portion 135b. The pressure measuring liquid discharged from the syringe section 140 flows to the nozzle section 123 of the cover 120 through the first supply channel section 135a, the pressure chamber section 151 and the second supply channel section 135b. do.

The membrane 153 is deformed when the pressure chamber portion 151 expands. The membrane 153 is formed of a flexible material. And the membrane 153 is brought into contact with the lower side of the pressure chamber portion 151. The peripheral portion of the membrane 153 is tightly attached to the pressure sensor portion 155 by the washer portion 154. The pressure sensor unit 155 senses the pressure change caused by the deformation of the membrane 153 and measures the pressure of the pressure measurement liquid. At this time, when the pressure measurement liquid is injected into the fascia of the human body through the needle portion 124, pressure balance is performed in the needle portion 124, the supply channel portion 135 and the pressure chamber portion 151. Therefore, the pressure at which the pressure measurement liquid is injected into the fascia can be measured in the pressure chamber portion 151.

The pressure sensor unit 155 may be of various types as long as the pressure of the pressure chamber unit 151 can be measured. For example, the pressure acting on the membrane 153 may be measured directly, or the change in the air pressure caused by the deformation of the membrane 153 may be directly measured. Various types of pressure sensor unit 155 may be applied.

The pressure driver 160 is connected to the syringe unit 140. The pressure driver 160 includes a first gear portion 161, a rotating rod portion 162, a second gear portion 163, a third gear portion 164, and a moving rod portion 165.

The first gear portion 161 is installed to be rotated by the operating portion 170. The rotation rod portion 162 is connected to the rotation shaft of the first gear portion 161 and is supported by the housing 110. One side of the rotation rod portion 162 is connected to the rotation shaft of the first gear portion 161 and the other side of the rotation rod portion 162 is supported on the supporter portion 167. The second gear portion 163 is axially coupled to the rotating rod portion 162. The second gear portion 163 is fixed to the rotating rod portion 162. The third gear portion 164 is engaged with the second gear portion 163 and slides on the second gear portion 163 during rotation of the second gear portion 163 to rotate along the longitudinal direction of the rotation rod portion 162 . The third gear portion 164 is formed thicker than the second gear portion 163. The moving rod portion 165 is axially coupled to the third gear portion 164 and urges the syringe portion 140 when the third gear portion 164 rotates so that the pressure measuring liquid is discharged from the syringe portion 140 . The moving rod section 165 is disposed in parallel with the rotating rod section 162.

As the first gear portion 161 is rotated by the operating portion 170, the rotating rod portion 162 is rotated. The second gear portion 163 is fixed to the rotation rod portion 162, and thus is rotated together with the rotation rod portion 162. The third gear portion 164 is fixed to the moving rod portion 165 and is engaged with the second gear portion 163 so that the third gear portion 164 slides in the second gear portion 163 and moves along the longitudinal direction of the rotating rod portion 162 . The movable rod portion 165 is moved along the longitudinal direction of the rotary rod portion 162 together with the third gear portion 164 to press the syringe portion 140. [ The pressure measurement liquid is discharged from the syringe section 140 as the syringe section 140 is pressed.

The moving rod portion 165 is provided with a moving screw portion 165a and the moving rod portion 165 is fixed with the third gear portion 164 and the moving rod portion 165 is fixed with the third gear portion 164 And is screwed to the supporter portion 167 so as to be moved together with the support portion 167. The third gear portion 164 is engaged with the second gear portion 163 and is rotated along the longitudinal direction of the rotating rod portion 162 since the moving rod portion 165 is screwed to the supporter portion 167 .

Further, the other end of the rotation rod portion 162 is rotatably supported on the supporter portion 167. The rotary rod portion 162 is not provided with a rotary threaded portion. The other end of the rotary rod portion 162 is rotatably supported by the supporter portion 167 so that the rotary rod portion 162 is rotatably supported by the rotary rod portion 162 when the first gear portion 161 and the second gear portion 163 rotate, (Not shown).

The operation unit 170 is installed in the housing 110 to drive the pressure driving unit 160. When the pressure driver 160 is driven by the operation unit 170, the pressure measuring liquid of the syringe unit 140 is supplied to the supply channel unit 135. [ A locking button portion 175 is provided at one side of the operating portion 170 to restrain the operating portion 170. [

The operation portion 170 includes an operation wheel portion 171 and an operation device portion 173. The operation wheel 171 is rotatably installed in the housing 110. The operation wheel 171 is formed in an annular shape so as to surround one side of the housing 110. The operating wheel portion 171 is slidably contacted to one side of the housing 110. The operation unit 173 is formed in an annular shape on the inner surface of the operation wheel 171. The first gear portion 161 provided to engage with the operation device unit 173 is rotated because the operation device unit 173 is rotated by the operation wheel unit 171. [ Accordingly, the first gear portion 161, the rotating rod portion 162, the second gear portion 163, the third gear portion 164, and the moving rod portion 165 are rotated do. At this time, the third gear portion 164 and the moving rod portion 165 move in parallel with the longitudinal direction of the rotating rod portion 162 to press the syringe portion 140.

When the operating wheel 171 and the operating unit 173 make one rotation, the moving rod unit 165 presses the syringe unit 140 such that 0.3 ml of the pressure measuring liquid is discharged from the syringe unit 140. Accordingly, since the rotation angle of the operation wheel 171 does not need to be finely adjusted by one rotation of the operation wheel 171, the amount of the pressure measuring liquid discharged from the syringe 140 can be accurately controlled.

The intrafascia pressure measurement apparatus 100 further includes a light emitting unit 181, a power supply unit 183, and a control unit 185.

The light emitting portion 181 is disposed on the cover 120. At this time, the light emitting portion 181 is disposed at the periphery of the cover 120. The light emitting portion 181 irradiates light having a different color to the periphery of the cover 120. For example, the light emitting portion 181 can emit red light and blue light.

The power supply unit 183 is disposed in the housing 110 and supplies power to the light emitting unit 181. The power supply unit 183 may be a primary battery or a secondary battery. A lead portion 115 may be provided on the other side of the housing 110 so that the power supply portion 183 can be replaced. Of course, a power supply unit 183 may be integrally provided in the housing 110, and a charging connection unit (not shown) may be installed in the housing 110 to charge the power supply unit 183. The configuration of the power supply unit 183 may be variously changed.

The control unit 185 controls the power supply unit 183 so that light is emitted from the light emitting unit 181 when the pressure measured by the pressure measuring unit 150 is equal to or higher than the set pressure. Since the user can recognize the pressure measured at the fascia by seeing the light emitted from the light emitting portion 181, it is possible to easily diagnose whether or not the compartment syndrome is present. Here, the setting pressure is 30 mmHg, which is the criterion of the pressure in the fascia to judge the compartment syndrome.

The control unit 185 controls the light emitting unit 181 to emit light of a different color from the light emitting unit 181 when the pressure measured by the pressure measuring unit 150 is equal to or higher than the set pressure. For example, when the pressure in the fascia is less than 30 mmHg, the light emitting portion 181 is controlled to emit blue light, and when the pressure in the fascia is 30 mmHg or more, the light emitting portion 181 may be controlled to emit red light have. In addition, if the pressure in the fascia is within the range of 10 to 20 mmHg, 20 to 30 mmHg, and 30 mmHg or more, if the pressure in the fascia falls within the range of the sea, the light emitting unit 181 may be controlled have. Since the color of the light emitted from the light emitting unit 181 varies according to the pressure measured by the pressure measuring unit 150, the user or the patient can recognize the presence or absence of the compartment syndrome based on the color of the light. The light emitting unit 181 is provided with an LED.

The intrafascia pressure measurement apparatus 100 further includes a display unit 187 disposed in the housing 110 and displaying a pressure measured by the pressure measurement unit 150. [ Since the pressure measured by the pressure measuring unit 150 is displayed on the display unit 187, the numerical value of the pressure in the fascia can be accurately known.

The operation of the apparatus for measuring pressure in the fascia according to an embodiment of the present invention will be described.

The syringe part 140 is inserted into the insertion part 132 of the holder part 130 and the pressure measuring part 150 is inserted into the receiving part 133 of the holder part 130. [ At this time, the washer 154 presses the membrane 153 against the pressure sensor unit 155. The holder 120 is fixed to the cover 120 so that the cover 120 is fastened to the housing 110 and the cover 120 and the holder 130 are installed in the housing 110 at the same time.

And the needle portion 124 is engaged with the nozzle portion 123 of the cover 120. The user grips the housing 110 and inserts the needle portion 124 at a certain depth into the fascia of the body.

After the needle portion 124 is inserted into the fascia, the operating wheel portion 171 is rotated one turn. The first gear portion 161, the rotating rod portion 162 and the second gear portion 163 are rotated as the operating wheel portion 171 is rotated. As the second gear portion 163 rotates, the third gear portion 164 engaged with the second gear portion 163 is rotated. As the third gear portion 164 is rotated, the moving rod portion 165 is rotated. The moving rod portion 165 is screwed with the supporter portion 167 and is moved along the longitudinal direction of the rotating rod portion 162 as the moving rod portion 165 is rotated. At this time, as the movable rod portion 165 is moved, the third gear portion 164 is moved relative to the second gear portion 163.

The pusher portion 143 of the syringe body 140 is pressed and the pusher portion 143 is moved along the syringe body 141 as the moving rod portion 165 is moved so that the pressure measuring solution of the syringe body 141 And is supplied to the supply channel unit 135. The pressure measuring liquid flowing along the supply channel portion 135 flows into the needle portion 124 through the nozzle portion 123 and the pressure measuring solution of the needle portion 124 is injected into the fascia. At this time, 30 ml of pressure measuring solution is injected into the inside of the fascia. The operation wheel 171 is rotated one turn to inject the pressure measuring solution into the fascia, so that the amount of the pressure measuring solution injected into the fascia can be corrected. Therefore, it is possible to prevent the pressure in the fascia from being inaccurately measured as the pressure measuring solution injected into the fascia is larger or smaller than the reference volume.

At this time, since the pressure of the pressure measuring liquid in the needle portion 124 equals the pressure of the pressure measuring liquid in the pressure chamber portion 151, the same pressure as the pressure of the pressure measuring liquid is applied to the pressure chamber portion 151 .

As the pressure chamber portion 151 is inflated, the membrane 153 is deformed and a pressure change occurs in the pressure sensor portion 155 due to the deformation of the membrane 153. Measures the pressure change at the pressure sensor unit 155, and transmits a signal regarding the pressure change to the control unit 185. [ The control unit 185 computes the received signal to calculate the pressure in the fascia.

If the control unit 185 determines that the pressure in the fascia is 30 mmHp or more, the control unit 185 controls the light emitting unit 181 to emit red light. Further, when it is determined that the pressure in the fascia is less than 30 mmHp, the control unit 185 controls the light emitting unit 181 to emit blue light.

The control unit 185 controls the display unit 187 to display the pressure in the fascia on the display unit 187. Accordingly, the user can accurately see the pressure in the fascia by looking at the display portion 187. [

As above. Since the supply of the pressure measurement liquid is controlled by the syringe unit 140 by rotating the operation unit 170, the amount of the pressure measurement liquid injected into the fascia can be accurately controlled. Since the amount of the pressure measuring solution injected into the inside of the fascia is accurately controlled, the pressure in the fascia can be accurately measured.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

100: pressure measuring device in the fascia 110: housing
120: cover 130: holder part
132: insertion portion 133: accommodating portion
135: supply channel section 140:
141: syringe body 143: pusher portion
150: pressure measuring unit 160: pressure driving unit
161: first gear portion 162:
163: second gear portion 164: third gear portion
165: moving rod portion 165a: moving thread portion
170: Operation part 171: Operation wheel part
173: Actuator tool part 175: Locking button part
181: light emitting portion 183: power supply portion
185: control unit 187:

Claims (9)

housing;
A cover coupled to the housing and to which a needle portion is connected;
A holder connected to the cover and disposed inside the housing;
A supply channel portion disposed in the holder portion to be connected to the needle portion;
A silent portion disposed in the holder portion and connected to the supply channel portion to supply a pressure measuring solution to the needle portion;
A pressure measuring unit disposed in the holder unit and measuring a pressure of the pressure measuring solution supplied to the supply channel unit;
A pressure driver connected to the syringe; And
And an operating part connected to the pressure driving part and rotatably installed in the housing to drive the pressure driving part.
The method according to claim 1,
The pressure-
A first gear portion installed to be rotated by the operating portion;
A rotating rod portion connected to a rotating shaft of the first gear portion and supported by the housing;
A second gear portion fixed to the rotary rod portion;
A third gear portion which meshes with the second gear portion and is moved along the longitudinal direction of the rotary rod portion together with the second gear portion when the second gear portion rotates; And
And a moving rod portion which is axially coupled to the third gear portion and presses the syringe portion when the third gear portion is rotated to discharge the pressure measuring liquid from the syringe portion.
3. The method of claim 2,
A moving thread portion is formed on an outer side surface of the moving rod portion,
The third gear portion is fixed to the moving rod portion,
Wherein the moving thread portion of the moving rod portion is screwed to the supporter portion so as to be moved together with the third gear portion.
3. The method of claim 2,
Wherein,
An operating wheel portion rotatably installed in the housing; And
And an actuator unit formed on an inner surface of the operation wheel unit to engage with the first gear unit.
The method according to claim 1,
Wherein the cover is detachably installed on one side of the housing,
Wherein the holder is fixed to the cover so as to be separated from the housing together with the cover.
The method according to claim 1,
An insertion portion formed in the holder portion to insert the syringe portion; and a receiving portion formed to receive the pressure measurement portion.
The method according to claim 1,
A light emitting portion disposed on the cover;
A power supply unit disposed in the housing and supplying power to the light emitting unit; And
And a controller for controlling the power supply unit such that light is emitted from the light emitting unit when the pressure measured by the pressure measuring unit is equal to or higher than a set pressure.
8. The method of claim 7,
Wherein the control unit controls the light emitting unit to emit light of a different color from that of the light emitting unit when the pressure measured by the pressure measuring unit is less than the set pressure.
9. The method of claim 8,
Further comprising a display unit disposed in the housing and configured to display a pressure measured by the pressure measuring unit.

Images