CN209766531U - battery mounting structure and capsule type biochemical parameter acquisition device - Google Patents

Abstract

The utility model relates to a battery mounting structure, which comprises a PCB (printed circuit board), wherein the PCB is provided with a battery mounting groove, the PCB is a rigid-flexible board, the main body of the PCB is a rigid board, the side wall of the battery mounting groove is provided with a first flexible board and a second flexible board, the upper surface and the lower surface of the first flexible board are both provided with positive conductive pads, and the upper surface and the lower surface of the second flexible board are both provided with negative conductive pads; when the battery to be assembled is clamped into the battery mounting groove, the battery pushes the first soft board and the second soft board, the positive electrode conducting pad of the first soft board is elastically pressed and contacted with the positive electrode of the battery, and the negative electrode conducting pad of the second soft board is elastically pressed and contacted with the negative electrode of the battery. Through the rigid-flex board, utilize the elastic deformation of flexible circuit board, realize the connection and the joint of battery, simple structure, reliability height. The utility model also provides a biochemical parameter acquisition device of capsule type who contains above-mentioned battery mounting structure.

Description

Battery mounting structure and capsule type biochemical parameter acquisition device

Technical Field

the utility model relates to an electronic product technical field, concretely relates to battery mounting structure and biochemical parameter acquisition device of capsule type.

Background

Increasingly, capsule-type devices are used for entering into the human or animal body for biochemical parameter acquisition.

the capsule type biochemical parameter acquisition device in the prior art has a complex battery mounting structure and low reliability.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: the utility model provides a battery mounting structure and contain this kind of mounting structure's biochemical parameter acquisition device of capsule type, simple structure, reliability are high.

a battery mounting structure comprises a PCB board provided with a battery mounting groove,

The PCB is a rigid-flexible board, the main body of the PCB is a rigid board, the side wall of the battery mounting groove is provided with a first flexible board and a second flexible board, the upper surface and the lower surface of the first flexible board are both provided with anode conductive pads, and the upper surface and the lower surface of the second flexible board are both provided with cathode conductive pads;

When the battery to be assembled is clamped into the battery mounting groove, the battery pushes the first soft board and the second soft board, the positive electrode conducting pad of the first soft board is elastically pressed and contacted with the positive electrode of the battery, and the negative electrode conducting pad of the second soft board is elastically pressed and contacted with the negative electrode of the battery.

Preferably, the hard board comprises a carrier medium and a circuit pattern, and the first soft board and the second soft board comprise a carrier medium and a circuit pattern;

the circuit pattern comprises a positive conductive circuit connected with the positive conductive pad and a negative conductive circuit connected with the negative conductive pad, the positive conductive circuit is attached to the hard board and the first soft board, and the negative conductive circuit is attached to the hard board and the second soft board.

Preferably, the first flexible board and the second flexible board are respectively disposed at both sides of the opposite faces of the battery.

Preferably, the hard board (hard printed circuit board) is a PCB (printed circuit board) with 4 layers or more, if the hard board is a four-layer printed circuit board, the hard board is respectively provided with an L1 layer, an L2 layer, an L3 layer and an L4 layer, and lines needing to be communicated among the four layers are connected through conductive through holes; in a general process, the FPCs serving as the first soft board and the second soft board are also the middle two layers (i.e., the L2 layer and the L3 layer) of the hard board, the laminated regions of the L2 layer and the L3 layer are normally wired as the common layer, and the external parts of the FPCs leak out of the positive electrode conductive pad and the negative electrode conductive pad. Preferably, the surface of the first flexible printed circuit board is provided with a first flat cable, and the first flat cable is a positive conductive pad.

Preferably, after the battery is clamped into the battery mounting groove, the first row line is bent, the middle upper part of the bent part is arched, and the elasticity of the bent part ensures that the positive electrode conductive pad is in reliable physical contact with the battery to form electrical connection;

The positive pole surface of battery is provided with anodal pit, and the part of bending of first winding displacement is blocked in anodal pit.

Preferably, the number of the positive pits is more than 3, the number of the first soft plates is more than 3, the positive pits are distributed in an array, and the first soft plates are distributed in an array;

the bending part of each first flat cable is clamped into an anode pit, or;

The bending part of more than 2 first flat cables is clamped into an anode pit.

Preferably, the sidewall of the battery mounting groove is provided with a first receiving groove;

After the battery is clamped into the battery mounting groove, the first soft board is bent, and the extending end of the first soft board is clamped into the first receiving groove.

preferably, the end of the second end of the first soft board is provided with a first magnetic suction head, the opening of the first receiving groove is provided with a first guide block, the first magnetic suction head is provided with a first magnetic suction block inside the first receiving groove, the first magnetic suction head can smoothly enter the first receiving groove under the action of the first guide block, and the first magnetic suction head smoothly presses and contacts the first magnetic suction block, so that the guide and effective positioning of the second end of the first soft board are realized.

Preferably, the battery clamping device further comprises a first shell, the first shell is provided with a circuit board mounting table and a battery clamping groove, and when the PCB is arranged on the circuit board mounting table, one end part of the battery to be assembled, which is clamped in, is clamped in the battery clamping groove.

a capsule type biochemical parameter acquisition device comprises a battery and a battery mounting structure.

Preferably, the battery mounting structure comprises a PCB, the PCB is provided with a battery mounting groove, the PCB is a rigid-flexible board, the main body of the PCB is a rigid board, the side wall of the battery mounting groove is provided with a first flexible board and a second flexible board, the upper surface and the lower surface of the first flexible board are both provided with positive conductive pads, and the upper surface and the lower surface of the second flexible board are both provided with negative conductive pads;

When the battery to be assembled is clamped into the battery mounting groove, the battery pushes the first soft board and the second soft board, the positive electrode conducting pad of the first soft board is elastically pressed and contacted with the positive electrode of the battery, and the negative electrode conducting pad of the second soft board is elastically pressed and contacted with the negative electrode of the battery.

Preferably, the hard board comprises a carrier medium and a circuit pattern, and the first soft board and the second soft board comprise a carrier medium and a circuit pattern;

The circuit pattern comprises a positive conductive circuit connected with the positive conductive pad and a negative conductive circuit connected with the negative conductive pad, the positive conductive circuit is attached to the hard board and the first soft board, and the negative conductive circuit is attached to the hard board and the second soft board.

Preferably, the first flexible board and the second flexible board are respectively disposed at both sides of the opposite faces of the battery.

Preferably, the surface of the first flexible printed circuit board is provided with a first flat cable, and the first flat cable is a positive conductive pad.

preferably, after the battery is clamped in the battery mounting groove, the first row line is bent;

the positive pole surface of battery is provided with anodal pit, and the part of bending of first winding displacement is blocked in anodal pit.

Preferably, the number of the positive pits is more than 3, the number of the first soft plates is more than 3, the positive pits are distributed in an array, and the first soft plates are distributed in an array;

The bending part of each first flat cable is clamped into an anode pit, or;

the bending part of more than 2 first flat cables is clamped into an anode pit.

Preferably, the sidewall of the battery mounting groove is provided with a first receiving groove;

after the battery is clamped into the battery mounting groove, the first soft board is bent, and the extending end of the first soft board is clamped into the first receiving groove.

preferably, the battery clamping device further comprises a first shell, the first shell is provided with a circuit board mounting table and a battery clamping groove, and when the PCB is arranged on the circuit board mounting table, one end part of the battery to be assembled, which is clamped in, is clamped in the battery clamping groove.

Preferably, the device also comprises a biochemical parameter acquisition board, wherein a signal transmission bonding pad is arranged on the biochemical parameter acquisition board, an elastic contact pin is arranged on the surface of the PCB, and after the biochemical parameter acquisition board is fixed, the elastic contact pin is elastically pressed and contacted on the signal transmission bonding pad.

The first shell is provided with a collection plate mounting platform, and the biochemical parameter collection plate is arranged on the collection plate mounting platform.

the device also comprises a second shell, and the second shell and the first shell form a closed whole.

preferably, a second flat cable is disposed on a surface of the second flexible board, and the second flat cable is a negative conductive pad.

Preferably, after the battery is clamped in the battery mounting groove, the second flat cable is bent;

the negative pole surface of battery is provided with the negative pole pit, and the part card of bending of second winding displacement is in the negative pole pit.

Preferably, the number of the negative electrode pits is more than 3, the number of the second soft plates is more than 3, the negative electrode pits are distributed in an array, and the second soft plates are distributed in an array;

The bending part of each second flat cable is clamped into a negative pit, or;

The bending part of more than 2 second flat cables is clamped into a negative pit.

Preferably, the sidewall of the battery mounting groove is provided with a second receiving groove;

After the battery is clamped into the battery mounting groove, the second soft board is bent, and the extending end of the second soft board is clamped into the second receiving groove.

The utility model has the advantages that: a battery mounting structure comprises a PCB, wherein the PCB is provided with a battery mounting groove, the PCB is a rigid-flexible board, the main body of the PCB is a rigid board, the side wall of the battery mounting groove is provided with a first flexible board and a second flexible board, the upper surface and the lower surface of the first flexible board are both provided with positive conductive pads, and the upper surface and the lower surface of the second flexible board are both provided with negative conductive pads; when the battery to be assembled is clamped into the battery mounting groove, the battery pushes the first soft board and the second soft board, the positive electrode conducting pad of the first soft board is elastically pressed and contacted with the positive electrode of the battery, and the negative electrode conducting pad of the second soft board is elastically pressed and contacted with the negative electrode of the battery. Through the rigid-flex board, utilize the elastic deformation of flexible circuit board, realize the connection and the joint of battery, simple structure, reliability height. The utility model also provides a biochemical parameter acquisition device of capsule type who contains above-mentioned battery mounting structure.

Drawings

The battery mounting structure of the present invention will be further described with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of the capsule-type biochemical parameter acquisition device of the present invention.

fig. 2 is an exploded view of the capsule-type biochemical parameter acquisition device of the present invention.

Fig. 3 is an exploded view of the first casing of the capsule-type biochemical parameter acquisition device of the present invention.

Fig. 4 is a schematic structural diagram of a battery mounting structure according to the present invention.

fig. 5 is a schematic view of the structure of the battery.

Fig. 6 is a sectional view of the capsule-type biochemical parameter collecting device of the present invention.

in the figure:

1-a PCB board; 11-a battery mounting groove; 111-a first receiving channel; 112-a second receiving slot; 12-hard board; 131-a first soft board; 1311-a first magnetic tip; 132-a second flexible board; 1321-a second magnetic tip; 141-a first guide block; 142-a second guide block; 2-a battery; 21-positive pits; 22-negative pits; 3-a first housing; 31-a circuit board mounting table; 32-battery card slot; 33-a collection plate mounting table; 4-biochemical parameter acquisition board; 5-an elastic contact pin; 6-a second shell; 7-chip.

Detailed Description

the battery mounting structure and the capsule type biochemical parameter collecting device of the present invention will be further described with reference to fig. 1 to 6.

a battery mounting structure comprises a PCB (printed circuit board) 1, wherein the PCB 1 is provided with a battery mounting groove 11, the PCB 1 is a rigid-flexible board, the main body of the PCB 1 is a hard board 12, the side wall of the battery mounting groove 11 is provided with a first soft board 131 and a second soft board 132, the upper surface and the lower surface of the first soft board 131 are both provided with positive conductive pads, and the upper surface and the lower surface of the second soft board 132 are both provided with negative conductive pads;

when the battery 2 to be assembled is inserted into the battery mounting groove 11, the battery 2 pushes the first soft plate 131 and the second soft plate 132, the positive electrode conductive pad of the first soft plate 131 is elastically pressed against the positive electrode of the battery 2, and the negative electrode conductive pad of the second soft plate 132 is elastically pressed against the negative electrode of the battery 2.

Through the soft and hard combination board, utilize the elastic deformation of first soft board 131 and second soft board 132, realize the connection and the joint of battery, simple structure, reliability height.

In this embodiment, the hard board 12 includes a carrier medium and a circuit pattern, and the first and second soft boards 131 and 132 include a carrier medium and a circuit pattern;

the circuit pattern includes a positive conductive trace connected to the positive conductive pad and a negative conductive trace connected to the negative conductive pad, the positive conductive trace being attached to the hard board 12 and the first soft board 131, and the negative conductive trace being attached to the hard board 12 and the second soft board 132.

In the present embodiment, the first soft plate 131 and the second soft plate 132 are respectively disposed on both sides of the opposite two faces of the battery 2.

In this embodiment, a first flat cable (a positive gold finger) is disposed on the surface of the first flexible board 131, and the first flat cable is a positive conductive pad.

In the embodiment, after the battery 2 is clamped in the battery mounting groove 11, the first row line is bent, the middle upper part of the bent part is arched, and the elasticity of the bent part ensures that the positive conductive pad is reliably in physical contact with the battery 2 to form electrical connection;

The positive electrode surface of the battery 2 is provided with a positive electrode pit 21, and the bent portion of the first flat cable is fitted into the positive electrode pit 21.

In this embodiment, the number of the positive pits 21 is more than 3, the number of the first soft plates 131 is more than 3, the positive pits 21 are distributed in an array, and the first soft plates 131 are distributed in an array;

The bending part of each first flat cable is clamped into one positive pit 21, or;

the bending parts of more than 2 first flat cables are clamped into a positive electrode pit 21.

In the present embodiment, the side wall of the battery mounting groove 11 is provided with a first receiving groove 111;

after the battery 2 is inserted into the battery mounting groove 11, the first flexible board 131 is bent, and the protruding end of the first flexible board 131 is inserted into the first receiving groove 111.

the first receiving groove 111 is used for realizing the reliable support of the second end of the first flexible board 131, the first end of the first flexible board 131 is laminated inside the hard board 12, and after the two ends of the first flexible board 131 are reliably supported, the first flexible board 131 can be in an elastic arched state, thereby ensuring the reliable connection and the press contact of the positive conductive pad of the first flexible board 131 and the positive electrode of the battery 2.

In this embodiment, a first magnetic attraction head 1311 is disposed at an end of the second end of the first flexible board 131, a first guiding block 141 is disposed at an opening of the first receiving groove 111, a first magnetic attraction block is disposed inside the first receiving groove 111, the first magnetic attraction head 1311 can smoothly enter the first receiving groove 111 under the action of the first guiding block 141, and the first magnetic attraction head 1311 smoothly presses and contacts the first magnetic attraction block, so as to guide and effectively position the second end of the first flexible board 131.

In this embodiment, the battery module further includes a first housing 3, the first housing 3 is provided with a circuit board mounting table 31 and a battery slot 32, and when the PCB 1 is disposed on the circuit board mounting table 31, one end of the battery 2 to be assembled is clamped into the battery slot 32.

In this embodiment, the PCB board 1 is provided with a chip 7.

A capsule type biochemical parameter acquisition device comprises a battery 2 and a battery mounting structure.

In this embodiment, the battery mounting structure includes a PCB 1, the PCB 1 is provided with a battery mounting groove 11, the PCB 1 is a rigid-flex board, a main body of the PCB 1 is a hard board 12, a first soft board 131 and a second soft board 132 are disposed on a side wall of the battery mounting groove 11, an anode conductive pad is disposed on each of upper and lower surfaces of the first soft board 131, and a cathode conductive pad is disposed on each of upper and lower surfaces of the second soft board 132;

When the battery 2 to be assembled is inserted into the battery mounting groove 11, the battery 2 pushes the first soft plate 131 and the second soft plate 132, the positive electrode conductive pad of the first soft plate 131 is elastically pressed against the positive electrode of the battery 2, and the negative electrode conductive pad of the second soft plate 132 is elastically pressed against the negative electrode of the battery 2.

In this embodiment, the hard board 12 includes a carrier medium and a circuit pattern, and the first and second soft boards 131 and 132 include a carrier medium and a circuit pattern;

The circuit pattern includes a positive conductive trace connected to the positive conductive pad and a negative conductive trace connected to the negative conductive pad, the positive conductive trace being attached to the hard board 12 and the first soft board 131, and the negative conductive trace being attached to the hard board 12 and the second soft board 132.

In the present embodiment, the first soft plate 131 and the second soft plate 132 are respectively disposed on both sides of the opposite two faces of the battery 2.

In this embodiment, a first flat cable is disposed on the surface of the first flexible board 131, and the first flat cable is a positive conductive pad.

In this embodiment, after the battery 2 is clamped into the battery mounting groove 11, the first bus bar is bent;

the positive electrode surface of the battery 2 is provided with a positive electrode pit 21, and the bent portion of the first flat cable is fitted into the positive electrode pit 21.

in this embodiment, the number of the positive pits 21 is more than 3, the number of the first soft plates 131 is more than 3, the positive pits 21 are distributed in an array, and the first soft plates 131 are distributed in an array;

The bending part of each first flat cable is clamped into one positive pit 21, or;

the bending parts of more than 2 first flat cables are clamped into a positive electrode pit 21.

in the present embodiment, the side wall of the battery mounting groove 11 is provided with a first receiving groove 111;

After the battery 2 is inserted into the battery mounting groove 11, the first flexible board 131 is bent, and the protruding end of the first flexible board 131 is inserted into the first receiving groove 111.

In this embodiment, the battery module further includes a first housing 3, the first housing 3 is provided with a circuit board mounting table 31 and a battery slot 32, and when the PCB 1 is disposed on the circuit board mounting table 31, one end of the battery 2 to be assembled is clamped into the battery slot 32.

In this embodiment, the device further comprises a biochemical parameter acquisition board 4, wherein a signal transmission pad is arranged on the biochemical parameter acquisition board 4, an elastic contact pin 5 is arranged on the surface of the PCB board 1, and after the biochemical parameter acquisition board 4 is fixed, the elastic contact pin 5 is elastically pressed and contacted on the signal transmission pad.

The first housing 3 is provided with a collection plate mounting table 33, and the biochemical parameter collection plate 4 is arranged on the collection plate mounting table 33.

the device also comprises a second shell 6, and the second shell 6 and the first shell 3 form a closed whole.

In this embodiment, a second flat cable (a negative electrode gold finger) is disposed on the surface of the second flexible board 132, and the second flat cable is a negative electrode conductive pad.

In this embodiment, after the battery 2 is clamped into the battery mounting groove 11, the second flat cable is bent;

The negative electrode surface of the battery 2 is provided with a negative electrode pit 22, and the bent part of the second flat cable is clamped into the negative electrode pit 22.

in this embodiment, the number of the negative electrode pits 22 is more than 3, the number of the second soft plates 132 is more than 3, the negative electrode pits 22 are distributed in an array, and the second soft plates 132 are distributed in an array;

The bent part of each second flat cable is clamped into one negative electrode pit 22, or;

The bending parts of more than 2 second flat cables are clamped into a negative electrode pit 22.

In the present embodiment, the side wall of the battery mounting groove 11 is provided with a second receiving groove 112;

After the battery 2 is inserted into the battery mounting groove 11, the second flexible board 132 is bent, and the protruding end of the second flexible board 132 is inserted into the second receiving groove 112.

In this embodiment, the end of the second flexible board 132 is provided with a second magnetic attraction head 1321, the opening of the first receiving slot 111 is provided with a second guiding block 142, the inside of the second receiving slot 112 is provided with a first magnetic attraction block, the second magnetic attraction head 1321 can smoothly enter the second receiving slot 112 under the action of the second guiding block 142, and the second magnetic attraction head 1321 smoothly presses and contacts the second magnetic attraction block, so as to guide and effectively position the second end of the second flexible board 132.

The utility model discloses a not be limited to above-mentioned embodiment, the technical scheme of above-mentioned each embodiment can the cross combination form new technical scheme each other, and all adopt the technical scheme who equates the replacement formation in addition all to fall into the utility model discloses the required protection within range.

Claims (10)

1. A battery mounting structure comprises a PCB (1), and is characterized in that the PCB (1) is provided with a battery mounting groove (11), the PCB (1) is a rigid-flexible board, the main body of the PCB (1) is a hard board (12), the side wall of the battery mounting groove (11) is provided with a first soft board (131) and a second soft board (132), the upper surface and the lower surface of the first soft board (131) are both provided with positive conductive pads, and the upper surface and the lower surface of the second soft board (132) are both provided with negative conductive pads;

When waiting battery (2) of assembly to block in battery mounting groove (11), battery (2) bulldoze first soft board (131) and second soft board (132), the anodal conductive pad elasticity pressure of first soft board (131) is touched the positive pole of battery (2), the negative pole conductive pad elasticity pressure of second soft board (132) is touched the negative pole of battery (2).

2. The battery mounting structure according to claim 1, wherein the hard sheet (12) includes a carrier medium and a circuit pattern, and the first soft sheet (131) and the second soft sheet (132) include a carrier medium and a circuit pattern;

The circuit pattern comprises a positive conductive circuit connected with the positive conductive pad and a negative conductive circuit connected with the negative conductive pad, the positive conductive circuit is attached to the hard board (12) and the first soft board (131), and the negative conductive circuit is attached to the hard board (12) and the second soft board (132).

3. The battery mounting structure according to claim 2, wherein the first soft plate (131) and the second soft plate (132) are respectively provided on both sides of the opposite two faces of the battery (2).

4. the battery mounting structure according to claim 3, wherein a surface of the first flexible board (131) is provided with a first flat cable, and the first flat cable is the positive conductive pad;

After the battery (2) is clamped into the battery mounting groove (11), the first bus bar is bent;

the positive pole surface of battery (2) is provided with anodal pit (21), the part of bending of first winding displacement is gone into anodal pit (21).

5. The battery mounting structure according to claim 4, wherein the number of the positive electrode recesses (21) is 3 or more, the number of the first soft plates (131) is 3 or more, the positive electrode recesses (21) are arranged in an array, and the first soft plates (131) are arranged in an array;

the bending part of each first flat cable is clamped into one positive electrode pit (21), or;

More than 2 bending parts of the first flat cable are clamped into one positive electrode pit (21).

6. The battery mounting structure according to claim 5, wherein a first magnetic attraction head (1311) is disposed at an end of the second end of the first flexible board (131), a first guide block (141) is disposed at an opening of the first receiving groove (111), a first magnetic attraction block is disposed inside the first receiving groove (111), the first magnetic attraction head (1311) can smoothly enter the first receiving groove (111) under the action of the first guide block (141), and the first magnetic attraction head (1311) smoothly presses and contacts the first magnetic attraction block, so that the second end of the first flexible board (131) is guided and effectively positioned.

7. The battery mounting structure according to any one of claims 6 or 5, wherein a side wall of the battery mounting groove (11) is provided with a first receiving groove (111);

After the battery (2) is clamped into the battery mounting groove (11), the first soft board (131) is bent, and the extending end of the first soft board (131) is clamped into the first receiving groove (111).

8. The battery mounting structure according to claim 7, further comprising a first housing (3), wherein the first housing (3) is provided with a circuit board mounting table (31) and a battery slot (32), and when the PCB board (1) is disposed on the circuit board mounting table (31), one end portion into which the battery (2) to be assembled is inserted into the battery slot (32).

9. A capsule type biochemical parameter acquisition device, comprising a battery (2), characterized by further comprising a battery mounting structure according to any one of claims 1 to 8.

10. The capsule biochemical parameter acquiring apparatus according to claim 9, further comprising a biochemical parameter acquiring board (4), wherein the biochemical parameter acquiring board (4) is provided with a signal transmitting pad, the surface of the PCB board (1) is provided with an elastic contact pin (5), and after the biochemical parameter acquiring board (4) is fixed, the elastic contact pin (5) is elastically pressed against the signal transmitting pad.