CN219331687U - Glass fiber reinforced plastic housing for medical imaging equipment - Google Patents

Abstract

The utility model discloses a glass fiber reinforced plastic housing for medical imaging equipment, which comprises a base, a housing connected to the base, and heat dissipation parts connected to two sides of the base and surrounding the two sides of the housing, wherein the housing comprises an upper housing and a lower housing clamped with the upper housing, mounting cavities are respectively arranged in the upper housing and the lower housing, the lower housing is detachably connected to the base, two sides of the upper part of the upper housing are connected with first connecting lugs, the heat dissipation parts comprise arc heat dissipation shells which are tightly attached to two sides of the housing, a plurality of heat dissipation holes are respectively formed in the inner wall and the outer wall of the heat dissipation shells, a plurality of fans are respectively arranged in the heat dissipation shells, the lower ends of the two heat dissipation shells are respectively detachably connected to two ends of the base, and the upper ends of the two heat dissipation shells are respectively connected with the first connecting lugs on one side of each through bolts. The heat dissipation part is tightly attached to the shell in a large area, so that the heat dissipation effect is good; the heat dissipation part, the shell and the base are independent and can be detached, and the heat dissipation part, the shell and the base are easy to transport, install and maintain.

Description

Glass fiber reinforced plastic housing for medical imaging equipment

Technical Field

The utility model relates to the technical field of medical equipment, in particular to a glass fiber reinforced plastic housing for medical imaging equipment.

Background

Medical imaging equipment includes CT, i.e. computerized tomography, which uses precisely collimated X-rays, gamma rays, ultrasonic waves, etc. to scan a cross section around a part of the human body one by one together with a detector of extremely high sensitivity.

The housing of CT machines generally adopts glass Fiber Reinforced Plastics (FRP), also known as GFRP, that is, fiber reinforced plastics, generally refers to reinforced plastics using glass fiber reinforced unsaturated polyester, epoxy resin and phenolic resin matrix, using glass fiber or its products as reinforcing material, known as glass fiber reinforced plastics, or glass fiber reinforced plastics, unlike toughened glass.

Most of the existing CT hood shells are integral, large in size and not easy to carry, mount and dismount, and the heat dissipation mechanism is not tightly attached to the hood shell in a large area, so that the heat dissipation effect is poor.

Disclosure of Invention

The utility model provides a glass fiber reinforced plastic housing for medical imaging equipment to solve the problems in the prior art.

In order to solve the technical problems, the utility model provides the following technical scheme:

the utility model provides a glass steel housing for medical imaging equipment, includes the base, connects the shell on the base, connects in the base both sides and surrounds the radiating portion in the shell both sides, the shell includes the casing, with last casing joint's lower casing, all is equipped with the installation cavity in last casing and the lower casing, the lower casing can be dismantled and connect on the base, the both sides on last casing upper portion are connected with first engaging lug, the radiating portion is including being the arc and hugging closely the radiating shell of shell both sides, the inner wall and the outer wall of radiating shell all are equipped with a plurality of louvres, be equipped with a plurality of fans in the radiating shell, two the lower extreme of radiating shell can be dismantled respectively and connect the both ends at the base, two the upper end of radiating shell passes through bolted connection with the first engaging lug of one side each respectively.

According to the technical scheme, when the detection element is installed, firstly, the lower shell is installed on the base, then the upper shell is clamped on the lower shell, so that the upper shell and the lower shell are initially positioned, then the heat dissipation part is installed on the base, the heat dissipation part is attached to the shell in a large area, and then the first connecting lug is connected with the heat dissipation shell, so that the heat dissipation part, the shell and the base form a whole. And each part is independent of each other, detachable, easy to transport, install and maintain.

Preferably, the two bottom surfaces of the upper shell are provided with clamping grooves, the two top surfaces of the lower shell are provided with clamping blocks matched with the clamping grooves, and the lower shell is clamped in the clamping grooves of the upper shell through the clamping blocks.

Above-mentioned technical scheme, with the draw-in groove joint of last casing on the fixture block of casing down, can carry out preliminary location with last casing and casing down to follow-up installation also dismantles easily simultaneously.

Preferably, the base is provided with a first mounting groove, the bottom surface of the lower shell is connected with a first mounting block, the first mounting block is inserted in the first mounting groove, the first mounting block and the base are provided with screw holes which are matched with each other,

above-mentioned technical scheme is pegged graft lower casing through first installation piece in first mounting groove, can realize the preliminary connection of lower casing and base, after first installation piece inserts in the first mounting groove, with first installation piece and base fixed connection through the bolt.

Preferably, the both ends of base are equipped with the second mounting groove, the lower extreme of heat dissipation shell is connected with the second installation piece, the second installation piece is pegged graft in the second mounting groove, the outside of heat dissipation shell lower extreme is connected with the second engaging lug, the both ends of base are connected with the third engaging lug that matches with the second engaging lug, and second engaging lug and third engaging lug pass through bolted connection.

According to the technical scheme, when the radiating part is installed, the second installation block on the radiating shell is inserted into the second installation groove of the base, and then the second connecting lug and the third connecting lug are connected through the bolts, so that the base and the radiating part are fixed.

The beneficial effects of the utility model are as follows: the heat dissipation part is tightly attached to the shell in a large area, so that the heat dissipation effect is good; the heat dissipation part, the shell and the base are independent and can be detached, and the heat dissipation part, the shell and the base are easy to transport, install and maintain.

Drawings

FIG. 1 is a cross-sectional view of the present utility model;

FIG. 2 is a schematic view of the housing;

in the figure: the heat radiation device comprises a 1-base, a 2-upper shell, a 3-lower shell, a 4-first connecting lug, a 5-heat radiation shell, a 6-fan, a 7-clamping groove, an 8-clamping block, a 9-first mounting groove, a 10-first mounting block, an 11-screw hole, a 12-second mounting groove, a 13-second mounting block, a 14-second connecting lug and a 15-third connecting lug.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-2, a glass fiber reinforced plastic housing for medical imaging equipment comprises a base 1, a housing connected to the base 1, and heat dissipation parts connected to two sides of the base 1 and surrounding two sides of the housing, wherein the housing comprises an upper housing 2 and a lower housing 3 clamped with the upper housing 2, specifically, two bottom surfaces of the upper housing 2 are provided with clamping grooves 7, two top surfaces of the lower housing 3 are provided with clamping blocks 8 matched with the clamping grooves, and the lower housing 3 is clamped in the clamping grooves 7 of the upper housing 2 through the clamping blocks 8.

The utility model discloses a detection device, including casing, lower casing, base 1, lower casing, upper casing 2 and lower casing 3, all be equipped with the installation cavity in casing 2 and lower casing 3, the installation cavity is used for installing detecting instrument, lower casing 3 can dismantle and connect on base 1, specifically, first mounting groove 9 has been seted up on the base 1, the bottom surface of casing 3 is connected with first installation piece 10 down, first installation piece 10 is pegged graft in first mounting groove 9, be equipped with the screw 11 of mutually supporting on first installation piece 10 and the base 1, after first installation piece 10 inserts in first mounting groove 9, through bolt with first installation piece 10 and base 1 fixed connection.

The utility model discloses a heat dissipation device, including an upper housing 2, including upper housing 2, the both sides on upper housing 2 upper portion are connected with first engaging lug 4, the radiating portion is including being the arc and hugging closely the heat dissipation shell 5 of shell both sides, two the upper end of heat dissipation shell 5 respectively with the first engaging lug 4 of one side respectively pass through bolted connection, the inner wall and the outer wall of heat dissipation shell 5 all are equipped with a plurality of louvres, be equipped with a plurality of fans 6 in the heat dissipation shell 5, two the lower extreme of heat dissipation shell 5 can be dismantled respectively and be connected at the both ends of base 1, specifically, the both ends of base 1 are equipped with second mounting groove 12, the lower extreme of heat dissipation shell 5 is connected with second installation piece 13, second installation piece 13 is pegged graft in second mounting groove 12, the outside of heat dissipation shell 5 lower extreme is connected with second engaging lug 14, the both ends of base 1 are connected with the third engaging lug 115 that matches with second engaging lug 14, and second engaging lug 14 passes through bolted connection.

The installation method of the utility model comprises the following steps:

in the mounting process, the detecting instrument is firstly mounted in the mounting cavities of the upper shell 2 and the lower shell 3, then the lower shell 3 is inserted into the first mounting groove 9 of the base through the first mounting block 10, then the base 1 and the first mounting block 10 are fixed through bolts, so that the lower shell 3 is kept stable, then the upper shell 2 is clamped on the lower shell 3, so that the upper shell 2 and the lower shell 3 are initially positioned, then the heat dissipation shell 5 is inserted into the second mounting groove 12 of the base through the second mounting block 13 and is connected with the third connecting lug 15 through the bolts, so that the heat dissipation part is mounted on the base 1, the heat dissipation part is tightly attached to the shell in a large area, then the first connecting lug 4 is connected with the heat dissipation shell 5, so that the heat dissipation part, the shell and the base form a whole, and the mounting is completed.

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a glass steel housing for medical imaging equipment, its characterized in that includes base (1), connects the shell on base (1), connects in base (1) both sides and surrounds the radiating portion in the shell both sides, the shell includes casing (2), with casing (3) down of last casing (2) joint, all be equipped with the installation cavity in last casing (2) and casing (3) down, casing (3) down can dismantle and connect on base (1), the both sides on last casing (2) upper portion are connected with first engaging lug (4), the radiating portion is including being arc and hugging closely shell both sides radiating shell (5), the inner wall and the outer wall of radiating shell (5) all are equipped with a plurality of louvres, be equipped with a plurality of fans (6) in radiating shell (5), two the lower extreme of radiating shell (5) can be dismantled respectively and connect the both ends at base (1), two the upper end of radiating shell (5) respectively with the first engaging lug (4) of one side each through bolted connection.

2. The glass fiber reinforced plastic housing for medical imaging equipment according to claim 1, wherein: two bottom surfaces of the upper shell (2) are provided with clamping grooves (7), two top surfaces of the lower shell (3) are provided with clamping blocks (8) matched with the clamping grooves, and the lower shell (3) is clamped in the clamping grooves (7) of the upper shell (2) through the clamping blocks (8).

3. The glass fiber reinforced plastic housing for medical imaging equipment according to claim 2, wherein: the base (1) is provided with a first mounting groove (9), the bottom surface of the lower shell (3) is connected with a first mounting block (10), and the first mounting block (10) is inserted into the first mounting groove (9).

4. A glass fiber reinforced plastic housing for medical imaging equipment according to claim 3, wherein: screw holes (11) matched with each other are formed in the first mounting block (10) and the base (1), and after the first mounting block (10) is inserted into the first mounting groove (9), the first mounting block (10) is fixedly connected with the base (1) through bolts.

5. A glass fiber reinforced plastic housing for medical imaging equipment according to claim 3, wherein: the base is characterized in that second mounting grooves (12) are formed in the two ends of the base (1), second mounting blocks (13) are connected to the lower ends of the radiating shells (5), the second mounting blocks (13) are inserted into the second mounting grooves (12), second connecting lugs (14) are connected to the outer sides of the lower ends of the radiating shells (5), third connecting lugs (15) matched with the second connecting lugs (14) are connected to the two ends of the base (1), and the second connecting lugs (14) and the third connecting lugs (15) are connected through bolts.

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