KR102247437B1 - Ultrasound probe for detecting heartbeat - Google Patents

Abstract

An object of the present invention is to provide an ultrasonic probe for detecting a heart rate that can improve detection accuracy by focusing an ultrasonic signal on a target position in the body. The ultrasonic probe for heart rate detection according to the present invention includes a housing having a signal transceiving surface facing the user's skin, and a center installed inside the housing to generate ultrasonic waves and transmit them to the user's body through the signal transceiving surface. An ultrasonic transducer and a plurality of side ultrasonic transducers disposed along the circumference of the center ultrasonic transducer and spaced apart from the center ultrasonic transducer inside the housing in order to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface A center ultrasonic transducer and a circuit board installed on the inside of the housing to be electrically connected to the plurality of side ultrasonic transducers, wherein each of the plurality of side ultrasonic transducers has an ultrasonic transmission direction corresponding to the ultrasonic transmission direction of the center ultrasonic transducer. It is arranged to be inclined by a predetermined inclination angle.

Description

Ultrasound probe for heart rate detection {ULTRASOUND PROBE FOR DETECTING HEARTBEAT}

The present invention relates to an ultrasonic probe, and more particularly, to a heartbeat detection ultrasonic probe capable of detecting a heartbeat by transmitting an ultrasonic signal to a target in the body and receiving an ultrasonic reflected signal reflected from the target.

A wide variety of medical devices using ultrasound have been developed and used. A medical device using ultrasound may transmit an ultrasound signal from the skin of an object toward a target area in the body, and check the internal state of the body by using information of the reflected ultrasound signal. Compared with other medical devices such as X-ray diagnostic devices, X-ray CT scanners, MRI, and nuclear medicine diagnostic devices, medical devices using such ultrasound are compact, inexpensive, and display in real time, and do not have exposure to X-rays. Since it has the advantage of high safety, it is widely used in a wide variety of fields.

For example, an ultrasound medical device used in obstetrics and gynecology may monitor the condition of a mother and a fetus in a non-invasive manner. The heart rate of the fetus is essential to check the condition of the fetus. The fetal heart rate contains important information indicating the health of the fetus, and it is an important diagnostic tool.

At the 7th week of pregnancy, the fetus's heart is completely formed and the internal organs are rapidly built.At this time, the heart is divided into the left and right ventricles, and the heart rate is beating as fast as 150 beats per minute, and then gradually decreases as it approaches term, about 120 beats per minute. Becomes. Therefore, it is possible to check the health of the fetus by measuring the fetal heart rate, and whether or not the fetus is growing normally in the mother's stomach by checking the transition of the fetal heart rate by week.

In general, an ultrasound medical apparatus includes an ultrasound probe for transmitting ultrasound to an object and receiving an echo signal from the object. The ultrasonic probe includes an ultrasonic transducer that converts an ultrasonic signal and an electrical signal to each other. These medical ultrasound devices measure the heart rate of the fetus using the Doppler principle based on ultrasound signals. That is, a method of detecting the reflected Doppler signal after transmitting an ultrasound signal to the heart of the fetus, and extracting the fetal heart rate from the detected Doppler signal is used.

In order to measure the fetal heart sound and fetal heart rate with high precision by the ultrasound signal, it is necessary to focus the ultrasound signal on the target position and receive the reflected signal.

However, the conventional ultrasonic probe has a problem in that the detection accuracy is inferior because the ultrasonic signal transmitted toward the fetus tends to be dispersed.

Registered Patent Publication No. 0961855 (2010. 06. 09.)

The present invention has been devised in view of the above-described points, and an object of the present invention is to provide an ultrasonic probe for detecting heart rate that can improve detection accuracy by focusing an ultrasonic signal on a target position in the body.

The ultrasonic probe for heart rate detection according to the present invention for solving the above object includes: a housing having a signal transmission/reception surface that can face the user's skin; A center ultrasonic transducer installed inside the housing to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface; A plurality of side ultrasonic transducers disposed along the periphery of the center ultrasonic transducer and spaced apart from the center ultrasonic transducer inside the housing in order to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface; And a circuit board installed inside the housing to be electrically connected to the center ultrasonic transducer and the plurality of side ultrasonic transducers, wherein each ultrasonic transmission direction of the plurality of side ultrasonic transducers is the center ultrasonic wave. It is arranged to be inclined by a predetermined inclination angle with respect to the ultrasound transmission direction of the transducer.

The signal transmission/reception surface may be formed in a flat type.

The signal transmission/reception surface may have a curved shape.

It is preferable that the size of the center ultrasonic transducer is larger than the size of the side ultrasonic transducer.

The housing includes a center mounting groove in which the center ultrasonic transducer is mounted, and a plurality of side mounting grooves disposed along the circumference of the center mounting groove so that the plurality of side ultrasonic transducers can be mounted respectively. And, it may include a housing cover coupled to the housing base so as to cover the upper portion of the housing base.

The ultrasonic probe for heart rate detection according to the present invention may include a ground member disposed inside the housing to electrically connect the circuit board and the housing to ground the circuit board to the housing.

The ground member may have a coil spring structure made of a conductive material.

The ground member may include an elastic body made of an elastically deformable material, and a conductive shell coupled to an outer surface of the elastic body to electrically connect the circuit board and the housing.

The ultrasonic probe for heart rate detection according to the present invention includes a center ultrasonic transducer capable of generating an ultrasonic signal and a plurality of side ultrasonic transducers, wherein each of the plurality of side ultrasonic transducers has an ultrasonic transmission direction of the center ultrasonic transducer. By arranging to be inclined by a predetermined inclination angle with respect to the transmission direction, the ultrasonic signal generated from the center ultrasonic transducer and the ultrasonic signal generated from each of the plurality of side ultrasonic transducers can be stably focused on the target in the body. Therefore, it is possible to increase the detection sensitivity for the target, there is an effect of improving the detection accuracy compared to the prior art.

In addition, the ultrasonic probe for heart rate detection according to the present invention can reduce a noise signal by grounding a circuit board electrically connected to the center ultrasonic transducer and the plurality of side ultrasonic transducers to the housing through a grounding member, thereby reducing a noise signal and performing more precise detection. It is possible to obtain a signal, and there is an effect of increasing detection accuracy.

1 and 2 are perspective views showing an ultrasonic probe for detecting heart rate according to an embodiment of the present invention.
3 and 4 are exploded views showing an ultrasonic probe for detecting heart rate according to an embodiment of the present invention.
5 is an excerpt of a part of FIG. 3.
6 shows an excerpt of a part of FIG. 4.
7 and 8 are cross-sectional views illustrating an ultrasonic probe for detecting heart rate according to an embodiment of the present invention.
9 is a plan view showing a partial configuration of an ultrasound probe for detecting heart rate according to an embodiment of the present invention.
10 shows an example of use of an ultrasound probe for detecting heart rate according to an embodiment of the present invention.
11 is a cross-sectional view showing an ultrasonic probe for detecting heart rate according to another embodiment of the present invention.

Hereinafter, an ultrasonic probe for detecting heart rate according to the present invention will be described in detail with reference to the drawings.

1 and 2 are perspective views showing an ultrasonic probe for detecting heart rate according to an embodiment of the present invention, and FIGS. 3 and 4 are exploded views showing an ultrasonic probe for detecting heart rate according to an embodiment of the present invention, and FIG. 5 3 shows an excerpt of a part of FIG. 3, FIG. 6 shows an excerpt of a part of FIG. 4, and FIGS. 7 and 8 are cross-sectional views illustrating an ultrasound probe for detecting heart rate according to an embodiment of the present invention.

As shown in the drawing, the ultrasonic probe 100 for heart rate detection according to an embodiment of the present invention includes a housing 110 and a center ultrasonic transducer 140 installed inside the housing 110 to generate an ultrasonic signal. ) And a plurality of side ultrasonic transducers 145, and a circuit board 150 installed inside the housing 110 to be electrically connected to the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145, , It includes a plurality of grounding members 170, 173, 175, 178 for grounding the circuit board 150 to the housing 110. The ultrasound probe 100 for detecting heart rate may be used to detect heart rate. That is, the ultrasonic probe for heart rate detection 100 may receive the ultrasonic reflection signal after transmitting the ultrasonic signal to the target heart, and extract the heart rate or heart sound of the heart from the detected ultrasonic reflection signal. In this embodiment, the ultrasound probe 100 for detecting heart rate detects the heart rate of the fetus by targeting the heart of the fetus (T), and transmits the detection signal to the main body (not shown) of the test apparatus in a wired manner. Explain.

The housing 110 accommodates a center ultrasonic transducer 140, a plurality of side ultrasonic transducers 145, a circuit board 150, and a plurality of ground members 170, 173, 175, and 178. And protect. The housing 110 includes a housing base 111 with an open top and a housing cover 125 coupled to the housing base 111. Between the housing base 111 and the housing cover 125, a center ultrasonic transducer 140, a plurality of side ultrasonic transducers 145, a circuit board 150, and a plurality of ground members 170, 173 ) A space for accommodating 175 and 178 is provided.

The housing base 111 has a signal transmission/reception surface 112 that can face the user's skin (S). The signal transmission/reception surface 112 is provided in a flat shape under the housing base 111. When the signal transmission/reception surface 112 faces the user's skin, the ultrasonic signals generated from the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 inside the housing 110 pass through the signal transmission/reception surface 112. Through this, it may be incident on the target T in the user's body. In addition, the ultrasonic reflected signal reflected from the target T in the user's body reaches the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 inside the housing 110 through the signal transmission/reception surface 112 can do. A center seating groove 114 in which the center ultrasonic transducer 140 can be seated is provided at an approximately central portion of the housing base 111, and a plurality of center seating grooves 114 inside the housing base 111 A plurality of side mounting grooves 115 in which the side ultrasonic transducers 145 can be respectively mounted are provided.

In addition, a housing connection groove 117 and a housing connection protrusion for installing some of the ground members 170, 173 among the plurality of ground members 170, 173, 175, and 178 inside the housing base 111 A plurality of coupling bosses 121 for coupling with 119 and the housing cover 125 are provided. The coupling boss 121 is provided with a coupling boss groove 122. In the housing connection groove 117 and the housing connection protrusion 119, a conductive part electrically connected to the ground member 170, 173 is disposed, and the ground members 170, 173 connect the housing connection groove 117 and the housing. By being coupled to the protrusions 119, respectively, it is possible to connect to a shield member (not shown) provided on the housing base 111 for electromagnetic shielding.

The housing cover 125 is coupled to the upper side of the housing base 111 to cover the open upper portion of the housing cover 125. Inside the housing cover 125, a housing connection groove 126 and a housing connection protrusion for installing some ground members 175, 178 among a plurality of ground members 170, 173, 175, and 178 128) is provided. In the housing connection groove 126 and the housing connection protrusion 128, a conductive part electrically connected to the ground members 175 and 178 is disposed, and the ground members 175 and 178 connect the housing connection groove 126 and the housing. By being coupled to the protrusions 128, respectively, it is possible to connect to a shield member (not shown) provided on the housing cover 125 for electromagnetic shielding.

In addition, the housing cover 125 is provided with a plurality of insertion holes 130 into which a plurality of fixing members 132 for fixing the housing base 111 and the housing cover 125 may be inserted. The housing cover 125 is in contact with the housing base 111 so as to cover the housing base 111, and the fixing member 132 passes through the insertion hole 130 and into the coupling boss groove 122 of the housing base 111. As it is inserted, it can be firmly fixed to the housing base 111.

A sealing member 134 is interposed between the housing base 111 and the housing cover 125. The sealing member 134 closes a gap between the housing base 111 and the housing cover 125. Due to the action of the sealing member 134, the housing base 111 and the housing cover 125 can be kept in a stable sealed state.

The sub-cover 136 and the hook 138 are coupled to the upper side of the housing cover 125. The sub-cover 136 covers the upper portion of the housing cover 125 so that the plurality of insertion holes 130 provided in the housing cover 125 are not exposed to the outside. The hook 138 is provided so as to protrude upwardly at an approximately central portion of the sub cover 136. The hook 138 may be used to connect a fixing belt or the like for fixing the housing 110 to the user's body.

The center ultrasonic transducer 140 is coupled to the center seating groove 114 of the housing 110 in order to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface 112. The center ultrasonic transducer 140 has a signal transceiving unit 141 for transmitting an ultrasonic signal to the outside and receiving an ultrasonic reflection signal reflected from a user's body. The center ultrasonic transducer 140 is disposed so that the signal transmission/reception unit 141 faces parallel to the signal transmission/reception surface 112 so as to transmit ultrasonic signals in a direction perpendicular to the flat signal transmission/reception surface 112. The center ultrasonic transducer 140 includes a piezoelectric ultrasonic transducer using the piezoelectric effect of a piezoelectric material, a magnetostrictive ultrasonic transducer using the magnetostrictive effect of a magnetic material, and a capacitance that transmits and receives ultrasonic waves using vibrations of hundreds or thousands of finely processed thin films. Micro-machined ultrasonic transducers and the like can be used with various known structures capable of converting an electrical signal into an ultrasonic signal and an ultrasonic signal into an electrical signal.

The plurality of side ultrasonic transducers 145 are respectively coupled to a plurality of side mounting grooves 115 provided in the housing 110 to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface 112. The plurality of side ultrasonic transducers 145 are spaced apart from the center ultrasonic transducer 140 and are disposed to surround the center ultrasonic transducer 140.

It is preferable that the plurality of side ultrasonic transducers 145 are spaced apart at regular intervals around the center ultrasonic transducer 140. In addition, it is preferable that the plurality of side ultrasonic transducers 145 are spaced apart from the center ultrasonic transducer 140 at regular intervals, respectively. That is, as shown in FIG. 9, when the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 are projected onto a virtual plane parallel to the signal transmission/reception surface 112 of the housing 110 , It is preferable that the center (Cs) of each of the plurality of side ultrasonic transducers 145 is placed on a virtual circle (Cv) centered on the center (Cc) of the center ultrasonic transducer (140). Through the arrangement of the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145, the ultrasonic signals generated from the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 are targeted (T). It is possible to focus more stably on the device, thereby increasing the detection accuracy.

The side ultrasonic transducer 145 has a signal transceiving unit 146 for transmitting an ultrasonic signal to the outside and receiving an ultrasonic reflected signal reflected from the user's body. The side ultrasonic transducer 145 is disposed so that the signal transmission/reception unit 146 is inclined with respect to the signal transmission/reception surface 112 so as to transmit ultrasonic signals in a direction inclined with respect to the flat signal transmission/reception surface 112.

Therefore, as shown in FIG. 10, the ultrasonic transmission direction of each of the plurality of side ultrasonic transducers 145 is inclined by a predetermined inclination angle α with respect to the ultrasonic transmission direction of the center ultrasonic transducer 140, and the center The ultrasonic signal generated from the ultrasonic transducer 140 and the ultrasonic signal generated from each of the plurality of side ultrasonic transducers 145 converge at a preset distance. In this way, by arranging the plurality of side ultrasonic transducers 145 to be inclined with respect to the center ultrasonic transducer 140 around the center ultrasonic transducer 140, the ultrasonic signal of the center ultrasonic transducer 140 and the plurality of The ultrasonic signals of each of the side ultrasonic transducers 145 may be converged to the target T. Accordingly, the ultrasonic signal of the center ultrasonic transducer 140 and the ultrasonic signal of each of the plurality of side ultrasonic transducers 145 can be focused on the target T, and ultrasonic reflection of the ultrasonic signal focused on the target T By receiving a signal, the detection sensitivity can be increased, and detection accuracy can be improved compared to the prior art.

The inclination angle α between the ultrasound transmission direction of the center ultrasound transducer 140 and the ultrasound transmission direction of the side ultrasound transducer 145 is the target distance D of the target T to be inspected by the ultrasound probe 100 for heart rate detection. ) Can be set in various ways. That is, if the target distance D of the ultrasound probe 100 for heart rate detection is relatively short, the inclination angle α between the ultrasound transmission direction of the center ultrasound transducer 140 and the ultrasound transmission direction of the side ultrasound transducer 145 is relative. Can be set largely. On the other hand, if the target distance D of the ultrasound probe 100 for heart rate detection is relatively long, the inclination angle α between the ultrasound transmission direction of the center ultrasound transducer 140 and the ultrasound transmission direction of the side ultrasound transducer 145 is relative. It can be set as small as.

The center ultrasonic transducer 140 includes a piezoelectric ultrasonic transducer using the piezoelectric effect of a piezoelectric material, a magnetostrictive ultrasonic transducer using the magnetostrictive effect of a magnetic body, and a capacitance for transmitting and receiving ultrasonic waves using vibrations of hundreds or thousands of finely processed thin films. Micro-machined ultrasonic transducers and the like can be used with various known structures capable of converting an electrical signal into an ultrasonic signal and an ultrasonic signal into an electrical signal.

The circuit board 150 is installed inside the housing 110 to electrically connect the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145. The circuit board 150 is provided with a plurality of connection portions 151, 152, 154, 155 electrically connected to the plurality of ground members 170, 173, 175, and 178. Hereinafter, among the plurality of connection parts 151, 152, 154, and 155, those disposed on the lower surface of the circuit board 150 are referred to as lower connection parts 151 and 152, and are disposed on the upper surface of the circuit board 150. This will be described by dividing it into upper connection parts 154 and 155. In this embodiment, two lower connection parts 151 and 152 and two upper connection parts 154 and 155 may be provided.

In addition, the circuit board 150 includes a signal generator for providing operation signals to the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145, and the center ultrasonic transducer 140 and a plurality of side ultrasonic transducers. A signal processing unit for processing an ultrasonic reflected signal received by the transducer 145 may be provided. Here, the signal processing unit may include an amplifying unit and a filter unit. The signal generating unit generates a pulse signal for generating an ultrasonic signal by the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145, and the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 Can provide. The amplification unit serves to amplify the ultrasonic reflected signals received by the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145. The filter unit may be composed of a high pass filter and a low pass filter, and may serve to remove noise from a signal amplified by the amplification unit. The signal processed first by the signal processing unit may be transmitted to the main body of the test apparatus, processed second, converted into a heartbeat signal, and then output through a speaker or a display.

As described above, since a processing method for obtaining a heart rate signal from an ultrasonic reflected signal is known, a detailed description thereof will be omitted.

The circuit board 150 is communicatively connected to the main body of the test apparatus through a connector 160. A cable 165 connected to the main body of the test apparatus is coupled to the connector 160. The signal detected by the ultrasound probe for heart rate detection 100 through the cable 165 is transmitted to the body of the testing device in a wired manner, and the ultrasonic probe for heart rate detection 100 through the cable 165 is an input signal of the body of the testing device. Can be received in a wired manner.

As shown in FIGS. 3 to 6 and 8, a plurality of ground members 170, 173, 175, 178 is a housing 110 to electrically connect the circuit board 150 and the housing 110. It is disposed on the inside of the circuit board 150 to ground the housing 110. Hereinafter, among the plurality of grounding members 170, 173, 175, and 178, those disposed under the circuit board 150 are referred to as lower grounding members 170 and 173, and on the upper side of the circuit board 150. It will be described by dividing it into the upper ground members 175 and 178 that are disposed. The lower ground members 170 and 173 ground the circuit board 150 to the housing base 111, and the upper ground members 175 and 178 ground the circuit board 150 to the housing cover 125.

The lower grounding members 170 and 173 are coupled to the block-shaped lower grounding member 170 inserted into the housing connection groove 117 of the housing base 111 and the housing connection protrusion 119 of the housing base 111 It may be divided into a lower ground member 173 in the form of a coil spring.

The block-shaped lower ground member 170 is coupled to the outer surface of the elastic body 171 in order to electrically connect the elastic body 171 made of an elastically deformable material and the circuit board 150 and the housing base 111. It includes a conductive sheath 172. The conductive shell 172 may be made of various conductive materials that can be deformed according to the deformation of the elastic body 171 such as a metal thin film. This block-shaped lower ground member 170 can maintain a stable connection to the housing base 111 by inserting one end into the housing connection groove 117, and the other end is provided on the lower surface of the circuit board 150. While being in contact with the lower connection part 151 to be compressed slightly, it is possible to stably maintain a connected state with the lower connection part 151. Accordingly, the lower ground member 170 may stably ground the circuit board 150 to the housing base 111.

The lower ground member 173 in the form of a coil spring can maintain a stable connection to the housing base 111 by coupling one end to the housing connection protrusion 119, and the other end is provided on the lower surface of the circuit board 150 While being in contact with the lower connection part 152 to be compressed slightly, it is possible to stably maintain a connected state with the lower connection part 152. Accordingly, the lower ground member 173 may stably ground the circuit board 150 to the housing base 111.

The upper grounding members 175 and 178 are coupled to the block-shaped upper grounding member 175 inserted into the housing connection groove 126 of the housing cover 125 and the housing connection protrusion 128 of the housing cover 125 It may be divided into an upper ground member 178 in the form of a coil spring.

The block-shaped upper ground member 175 electrically connects the elastic body 176 made of an elastically deformable material, the circuit board 150 and the housing cover 125, like the block-shaped lower ground member 170 described above. It includes a conductive sheath 177 coupled to the outer surface of the elastic body 176 for connection. The conductive sheath 177 may be made of various conductive materials that can be deformed according to the deformation of the elastic body 176 such as a metal thin film. Such a block-shaped upper ground member 175 can maintain a state stably connected to the housing cover 125 by inserting one end into the housing connection groove 126, and the other end is provided on the upper surface of the circuit board 150. While being in contact with the upper connection part 154 to be compressed somewhat, it is possible to stably maintain a connected state with the upper connection part 154. Accordingly, the upper ground member 175 may stably ground the circuit board 150 to the housing cover 125.

The coil spring-shaped upper ground member 178 has one end coupled to the housing connection protrusion 128 to maintain a stable connection to the housing cover 125, and the other end is provided on the lower surface of the circuit board 150. While being in contact with the upper connection part 155 to be compressed somewhat, it is possible to stably maintain a connected state with the upper connection part 155. Accordingly, the upper ground member 178 can stably ground the circuit board 150 to the housing cover 125.

In this way, the ground members 170, 173, 175, and 178 electrically connect the circuit board 150 to the housing 110 to ground the circuit board 150 to the housing 110, thereby generating a noise signal. This can be reduced, and detection accuracy through the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 can be improved.

In addition, a part of the ground member 170, 173, 175, 178 is coupled to the housing base 111, and the other part is coupled to the housing cover 125, so that the circuit board 150 and the housing base 111 And in the process of assembling the housing cover 125, the circuit board 150 may be naturally grounded to the housing 110. Therefore, the assembly time can be shortened.

As described above, the ultrasound probe 100 for heart rate detection according to an embodiment of the present invention includes a center ultrasound transducer 140 and a plurality of side ultrasound transducers 145 capable of generating an ultrasound signal. The side ultrasonic transducer 145 is arranged so that each ultrasonic transmission direction is inclined by a predetermined inclination angle α with respect to the ultrasonic transmission direction of the center ultrasonic transducer 140, thereby occurring in the center ultrasonic transducer 140. It is possible to stably focus the ultrasonic signal generated by the ultrasonic signal and the ultrasonic signal generated from each of the plurality of side ultrasonic transducers 145 on the target T in the body. Accordingly, detection sensitivity for the target T can be increased, and detection accuracy can be improved compared to the conventional one.

In addition, the ultrasonic probe 100 for heart rate detection according to an embodiment of the present invention connects the circuit board 150 electrically connected to the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 to a ground member ( By grounding the housing 110 through the 170) 173, 175, 178, noise signals can be reduced, a more precise detection signal can be obtained, and detection accuracy can be improved.

Meanwhile, FIG. 11 is a cross-sectional view showing an ultrasonic probe for detecting heart rate according to another embodiment of the present invention.

The ultrasonic probe 200 for heart rate detection shown in FIG. 11 includes a housing 210, a center ultrasonic transducer 140 installed inside the housing 210 to generate an ultrasonic signal, and a plurality of side ultrasonic transducers 145. ), a circuit board 150 installed inside the housing 210 to be electrically connected to the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145, and the circuit board 150 to the housing 110 ) And a plurality of grounding members (not shown) for grounding. The heartbeat detection ultrasonic probe 200 has a slightly modified structure of the housing 210 compared to the heartbeat detection ultrasonic probe 100 described above, and the rest of the configuration is the same as described above.

The housing 210 transmits the ultrasonic signals generated from the center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 into the user's body and receives the ultrasonic reflection signal reflected from the user's skin. A signal transmission/reception surface 211 facing (S) is provided, and the signal transmission/reception surface 211 is formed in a curved shape corresponding to the shape of the user's skin (S). The center ultrasonic transducer 140 and the plurality of side ultrasonic transducers 145 are disposed so as to face the signal transceiving surface 211 in the shape of a curved surface, so that ultrasonic signals generated from each may be focused on a target in the body.

Although a preferred example has been described for the present invention, the scope of the present invention is not limited to the form described and illustrated above.

For example, a center ultrasonic transducer 140 and a plurality of side ultrasonic transducers 145 are provided in the housing to transmit ultrasonic signals generated from the user's body and receive ultrasonic reflection signals reflected from the user's body. The shape of the signal transmission/reception surface is not limited to the illustrated one and may be variously changed.

In addition, although the drawing shows that the center ultrasonic transducer 140 and the side ultrasonic transducer 145 are formed in a circular shape, the diameter of the center ultrasonic transducer 140 is larger than the diameter of the side ultrasonic transducer 145. , The shape or size of the center ultrasonic transducer or the side ultrasonic transducer can be variously changed.

In addition, the drawings show that a plurality of grounding members for grounding the circuit board 150 to the housing are disposed on the lower side of the circuit board 150 and on the upper side of the circuit board 150, respectively. The number can be changed in various ways. And, as shown, the ground member is changed to various other structures capable of grounding the circuit board 150 to the housing, in addition to the block form including the elastic body and the conductive shell coupled to the outer surface of the elastic body, or the coil spring form. Can be.

In addition, although it was previously described that the ultrasound probe 100 for heart rate detection according to the present invention communicates with the testing device body in a wired manner through a cable 165, the ultrasonic probe for heart rate detection communicates with the testing device body in a wireless manner. It can have a structure to do.

In addition, it has been previously described that the heart rate detection ultrasound probe 100 according to the present invention targets the heart of the fetus and measures the heart rate of the fetus. However, the ultrasound probe for heart rate detection targets the heart of the user other than the fetus. It can be used to detect the heart rate of a person.

As described above, the present invention has been shown and described in connection with a preferred embodiment for illustrating the principle of the present invention, but the present invention is not limited to the configuration and operation as shown and described as such. Rather, it will be well understood by those skilled in the art that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims.

100, 200: ultrasound probe for heart rate detection
110, 210: housing 111: housing base
112, 211: signal transmitting and receiving surface 114: center mounting groove
115: side mounting groove 117, 126: housing connection groove
119, 128: housing connection protrusion 125: housing cover
132: fixing member 134: sealing member
136: sub cover 138: hook
140: center ultrasonic transducer 141, 146: signal transceiving unit
145: side ultrasonic transducer 150: circuit board
151, 152: lower connection part 154, 155: upper connection part
160: connector 165: cable
170, 173: lower ground member 175, 178: upper ground member

Claims (8)

A housing having a signal transmission/reception surface facing the user's skin;
A center ultrasonic transducer installed inside the housing to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface;
A plurality of side ultrasonic transducers disposed along the circumference of the center ultrasonic transducer and spaced apart from the center ultrasonic transducer inside the housing to generate ultrasonic waves and transmit them to the user's body through the signal transmission/reception surface;
A circuit board installed inside the housing to be electrically connected to the center ultrasonic transducer and the plurality of side ultrasonic transducers; And
Including; a grounding member disposed inside the housing to electrically connect the circuit board and the housing to ground while compressing the circuit board and the housing,
The plurality of side ultrasonic transducers are arranged such that each ultrasonic transmission direction is inclined by a predetermined inclination angle with respect to the ultrasonic transmission direction of the center ultrasonic transducer,
The ultrasonic probe for heart rate detection, characterized in that the size of the center ultrasonic transducer is larger than the size of the side ultrasonic transducer.
The method of claim 1,
The ultrasonic probe for heart rate detection, characterized in that the signal transceiving surface is made of a flat type.
The method of claim 1,
The ultrasonic probe for heart rate detection, characterized in that the signal transceiving surface is made of a curved surface.
delete The method of claim 1,
The housing,
A housing base having a center seating groove in which the center ultrasonic transducer is seated, and a plurality of side seating grooves disposed along the circumference of the center seating groove so that the plurality of side ultrasonic transducers can be seated, respectively,
And a housing cover coupled to the housing base to cover an upper portion of the housing base.
delete The method of claim 1,
The ground member is an ultrasonic probe for heart rate detection, characterized in that it has a coil spring structure made of a conductive material.
The method of claim 1,
The ground member,
An elastic body made of an elastically deformable material,
And a conductive shell coupled to an outer surface of the elastic body to electrically connect the circuit board and the housing.

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