CN210204742U - Bluetooth wireless oxyhemoglobin saturation monitoring probe - Google Patents

Abstract

The utility model discloses a bluetooth wireless oxyhemoglobin saturation monitoring probe, which comprises a fingerstall type photoelectric sensor, wherein a wireless communication box is arranged on the fingerstall type photoelectric sensor, a bluetooth transmitting module and a power module are arranged in the wireless communication box, the bluetooth transmitting module is provided with a bluetooth receiving module matched with the bluetooth transmitting module, and the bluetooth receiving module is provided with a PS/2 plug; the side of the fingerstall type photoelectric sensor is provided with an elastic belt, rectangular through holes are arranged on the elastic belt at intervals, and a sponge layer is arranged inside the fingerstall type photoelectric sensor. The utility model discloses the advantage lies in that the signal passes through bluetooth wireless transmission and gives the monitor host computer, does not have any external connection above the blood oxygen monitor probe, and is completely independent, and the user can move about at will after sheatheeing in, can not appear the circuit and drag the condition that drops, avoids monitoring blood oxygen in-process circuit to bring the constraint sense for the patient, effectively improves patient's experience of seeking medical advice and inspection. And the monitor is not limited by the length of the line, and is selected to be placed at a more appropriate position, so that the convenience is greatly improved.

Description

Bluetooth wireless oxyhemoglobin saturation monitoring probe

Technical Field

The utility model relates to the technical field of medical appliances, concretely relates to wireless oxyhemoglobin saturation monitor probe of bluetooth.

Background

The vital sign monitor is an instrument with functions of monitoring non-invasive blood pressure (NIBP), pulse rate, Mean Arterial Pressure (MAP), blood oxygen saturation (SpO2), body temperature and the like, and is required to be used in various clinical departments of a hospital. Measuring oxyhemoglobin saturation is one of them important function of monitor, and traditional monitor need use monitor (blood oxygen dactylotheca) and lead the line when measuring oxyhemoglobin saturation, and monitor sleeve is at patient's finger end, leads line connection monitor and monitor host computer, with oxyhemoglobin saturation signal transmission to monitor host computer that detects.

Because the monitor needs to collect various physical sign information and each collecting end needs to use a lead wire to transmit signals, the monitor has various connecting lines and brings difficulty to the operation of medical staff; and, receive the restriction of the length of line of leading, the monitor need be close to the sick bed during use, and can not move at will, otherwise easily pull and drop, lead to monitoring interrupt even instrument damage. In addition, the activity of the patient is limited in the dynamic blood oxygen monitoring process, and certain constraint is brought to the patient.

Therefore, we have studied an oximetry probe that does not require a lead wire to transmit a signal to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a bluetooth wireless oxyhemoglobin saturation monitor probe, it passes blood oxygen saturation signal through bluetooth wireless mode to solve the multiple problem that lead wire transmission signal brought.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the Bluetooth wireless oxyhemoglobin saturation monitoring probe comprises a fingerstall type photoelectric sensor, wherein a wireless communication box is arranged on the fingerstall type photoelectric sensor, a Bluetooth transmitting module and a power supply module are arranged in the wireless communication box, the signal input end of the Bluetooth transmitting module is connected with the signal output end of the fingerstall type photoelectric sensor, the power supply module supplies power to the fingerstall type photoelectric sensor and the Bluetooth transmitting module, the Bluetooth transmitting module is provided with a Bluetooth receiving module matched with the Bluetooth transmitting module, the Bluetooth receiving module and the fingerstall type photoelectric sensor are split, and the Bluetooth receiving module is provided with a PS/2 plug;

the side of the fingerstall type photoelectric sensor is provided with an elastic belt, rectangular through holes are formed in the elastic belt at intervals, and a sponge layer is arranged inside the fingerstall type photoelectric sensor.

The further improvement is that the top of the wireless communication box is provided with a heat dissipation hole.

The wireless communication box is further improved in that a translation switch port is arranged at the top of the wireless communication box and is positioned right above the power module.

The further improvement is that the Bluetooth receiving module and the Bluetooth transmitting module both adopt HC-05 Bluetooth modules.

The finger-stall type photoelectric sensor is further improved in that a photoelectric sensor with the model number of TSL250RD is adopted.

The beneficial effects of the utility model reside in that: the utility model discloses the oxyhemoglobin saturation signal that blood oxygen monitor obtained is through bluetooth wireless transmission for the monitor host computer for do not have any external connection circuit above the blood oxygen monitor, it is completely independent, the user can move about at will after sheatheeing in, the circuit can not appear and drags the condition that drops, avoids monitoring blood oxygen in-process circuit to bring the constraint sense for the patient, effectively improves patient's experience of seeking medical advice and inspection. And the monitor can be selectively placed at a more appropriate position without being limited by the length of a line, so that the convenience is greatly improved.

Drawings

FIG. 1 is a schematic view of a part of the structure of the present invention;

FIG. 2 is a schematic structural diagram of a Bluetooth receiving module and a PS/2 plug;

FIG. 3 is a control schematic diagram of the present invention;

in the figure: 1. a fingerstall type photoelectric sensor; 2. a wireless communication box; 3. a Bluetooth transmitting module; 4. a power supply module; 5. a Bluetooth receiving module; 6. a PS/2 plug; 7. an elastic band; 8. a rectangular through hole; 9. a sponge layer; 10. heat dissipation holes; 11. the gateway is translated away.

Detailed Description

The present application will now be described in further detail with reference to the drawings, it should be noted that the following detailed description is given for illustrative purposes only and is not to be construed as limiting the scope of the present application, as those skilled in the art will be able to make numerous insubstantial modifications and adaptations to the present application based on the above disclosure.

Referring to fig. 1 to 3, the bluetooth wireless oxyhemoglobin saturation monitoring probe comprises a fingerstall type photoelectric sensor 1, a wireless communication box 2 is arranged on the fingerstall type photoelectric sensor 1, a bluetooth transmitting module 3 and a power module 4 are arranged in the wireless communication box 2, a signal input end of the bluetooth transmitting module 3 is connected with a signal output end of the fingerstall type photoelectric sensor 1, the power module 4 supplies power to the fingerstall type photoelectric sensor 1 and the bluetooth transmitting module 3, the bluetooth transmitting module 3 is provided with a bluetooth receiving module 5 matched with the bluetooth transmitting module 3, the bluetooth receiving module 5 and the fingerstall type photoelectric sensor 1 are split, and the bluetooth receiving module 5 is provided with a PS/2 plug 6;

in addition, an elastic belt 7 is arranged on the side edge of the fingerstall type photoelectric sensor 1, rectangular through holes 8 are arranged on the elastic belt 7 at intervals, the elastic belt 7 can enable the fingerstall type photoelectric sensor 1 to be opened and closed according to the thickness of fingers for adjustment, and the rectangular through holes 8 can reduce the tension of the elastic belt 7 to a certain degree, so that the fingerstall type photoelectric sensor 1 can be more comfortably sleeved on the fingers; the inside of fingerstall formula photoelectric sensor 1 is equipped with sponge layer 9, and sponge layer 9 can further increase the comfort level, also enables the inside of fingerstall formula photoelectric sensor 1 and obtains filling, and the parcel nature is better, effectively avoids the dactylotheca to drop.

The embodiment of the utility model provides an in, 2 tops of wireless communication box are equipped with louvre 10 for keep the inside permeability of wireless communication box 2, avoid the temperature rise under the sealed environment.

The embodiment of the utility model provides an in, 2 portions in wireless communication box top are equipped with translation switch port 11, and translation switch port 11 is located directly over power module 4, but translation switch port 11 translation must pull open, can change or charge power module 4 after pulling open.

In the embodiment of the present invention, HC-05 bluetooth module is selected for use by bluetooth receiving module 5 and bluetooth transmitting module 3.

In the embodiment of the present invention, the photoelectric sensor of TSL250RD is adopted in fingerstall type photoelectric sensor 1.

When the finger stall type photoelectric sensor is used specifically, the finger stall type photoelectric sensor 1 is sleeved on the finger tip of a patient, the photoelectric sensor in the finger stall type photoelectric sensor is enabled to monitor the blood oxygen saturation degree, monitoring signals are sent to the Bluetooth receiving module 5 through the Bluetooth transmitting module 3, the Bluetooth receiving module 5 is inserted into a monitor host through the PS/2 plug 6, therefore, the signals are transmitted, and the PS/2 plug 6 can be matched with most of monitor hosts on the current market.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (5)

1. Bluetooth wireless oxyhemoglobin saturation monitor probe, including fingerstall formula photoelectric sensor (1), its characterized in that: the fingerstall-type photoelectric sensor is characterized in that a wireless communication box (2) is arranged on the fingerstall-type photoelectric sensor (1), a Bluetooth transmitting module (3) and a power supply module (4) are arranged in the wireless communication box (2), the signal input end of the Bluetooth transmitting module (3) is connected with the signal output end of the fingerstall-type photoelectric sensor (1), the power supply module (4) supplies power to the fingerstall-type photoelectric sensor (1) and the Bluetooth transmitting module (3), the Bluetooth transmitting module (3) is provided with a Bluetooth receiving module (5) matched with the Bluetooth transmitting module, the Bluetooth receiving module (5) and the fingerstall-type photoelectric sensor (1) are split, and the Bluetooth receiving module (5) is provided with a PS/2 plug (6);

the side of the fingerstall type photoelectric sensor (1) is provided with an elastic belt (7), rectangular through holes (8) are arranged on the elastic belt (7) at intervals, and a sponge layer (9) is arranged inside the fingerstall type photoelectric sensor (1).

2. The bluetooth wireless blood oxygen saturation monitoring probe according to claim 1, characterized in that: the top of the wireless communication box (2) is provided with a heat dissipation hole (10).

3. The bluetooth wireless blood oxygen saturation monitoring probe according to claim 1, characterized in that: the top of the wireless communication box (2) is provided with a horizontal moving gateway (11), and the horizontal moving gateway (11) is positioned right above the power module (4).

4. The bluetooth wireless blood oxygen saturation monitoring probe according to claim 1, characterized in that: and the Bluetooth receiving module (5) and the Bluetooth transmitting module (3) both adopt HC-05 Bluetooth modules.

5. The bluetooth wireless blood oxygen saturation monitoring probe according to claim 1, characterized in that: the fingerstall type photoelectric sensor (1) adopts a photoelectric sensor with the model number of TSL250 RD.

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