CN216593835U - Frame of temperature sensor fixed point monitoring - Google Patents

Abstract

The utility model provides a frame of temperature sensor fixed point monitoring, includes four vertical stands, four upper connection crossbeams, sensor installation crossbeam one, sensor installation crossbeam two, sensor installation crossbeam three, central temperature sensor, four bight monitoring sensor, two activity sensors and activity sensor drive arrangement, activity sensor drive arrangement can drive two activity sensors and remove in the rectangular frame that four vertical stands and four upper connection crossbeams constitute. The rack for fixed-point monitoring of the temperature sensor disclosed by the utility model has the advantages that the fixed sensor and the movable sensor are combined, so that the temperature monitoring can be carried out on each point in the cross section range of the rack, the arranged movable sensor can continuously move circularly in the range of the cross section occupied by the rack, the temperature of the blank area between the fixed temperature sensors is monitored, the reliability of the temperature monitoring can be ensured, and the omnibearing monitoring can be carried out in the space range of the rack.

Description

Frame of temperature sensor fixed point monitoring

Technical Field

The utility model belongs to the technical field of mechanical basic parts, and particularly relates to a rack for fixed-point monitoring of a temperature sensor.

Background

As is well known, lithium batteries have the advantages of high energy, light weight, and long service life, and are widely used in many fields such as new energy vehicles. In the process of building a production line of the lithium battery, a frame structure is mostly needed, and due to the frame structure, the reactor or equipment can be supported and simultaneously a certain anti-seismic effect is achieved. The machines and the equipment in the frame are connected with each other through the pipelines, so that the working efficiency of the equipment is improved, and the tidiness and the aesthetic degree of the production line are improved.

But the current frame only plays the supporting role, but to this kind of special product of lithium cell, some processes need rationally control the temperature, keep the stability of workshop operational environment. The temperature monitoring in the production line is only carried out by arranging a temperature sensor in a workshop or manually measuring the temperature of the workshop, but no system temperature control system is used for controlling the temperature.

Therefore, a need exists for a rack structure that is capable of a stable combination of temperature and support.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: the utility model aims to provide a rack for fixed-point monitoring of a temperature sensor, and solves the problems that the rack in the prior art is single in function, only plays a simple supporting role and reduces the functions of the rack.

The technical scheme is as follows: the utility model provides a rack for fixed-point monitoring of a temperature sensor, which comprises four vertical upright posts, four upper connecting cross beams, a first sensor mounting cross beam, a second sensor mounting cross beam, a third sensor mounting cross beam, a central temperature sensor, four corner monitoring sensors, two movable sensors and a movable sensor driving device, wherein the upper ends of the four vertical upright posts are connected through the four upper connecting cross beams, the four vertical upright posts and the four upper connecting cross beams form a rectangular frame structure, the first sensor mounting cross beam, the second sensor mounting cross beam and the third sensor mounting cross beam are arranged in parallel, the first sensor mounting cross beam, the second sensor mounting cross beam and the third sensor mounting cross beam are arranged on the upper connecting cross beams, the second sensor mounting cross beam is positioned between the first sensor mounting cross beam and the third sensor mounting cross beam, the central temperature sensor is arranged on the second sensor mounting cross beam, four bight monitoring sensors set up on sensor installation crossbeam one and sensor installation crossbeam three, activity sensor drive arrangement sets up on sensor installation crossbeam one, sensor installation crossbeam two and sensor installation crossbeam three, two activity sensors and activity sensor drive arrangement connect, activity sensor drive arrangement can drive two activity sensors and remove in the rectangular frame that four vertical stands and four upper connection crossbeams constitute.

Furthermore, in the rack for fixed-point monitoring of the temperature sensors, the central temperature sensor is located in the center of the rectangular cross section where the four upper connecting beams are located.

Furthermore, in the rack for fixed-point monitoring of the temperature sensor, the four corner monitoring sensors are located at four corner positions of the rectangular section where the four upper connecting beams are located.

Further, in the rack for fixed-point monitoring of the temperature sensor, the lower end part of the vertical upright post is provided with the fixed mounting plate, a group of reinforcing rib plates are arranged between the fixed mounting plate and the vertical upright post, and the group of reinforcing rib plates are arranged in an annular array manner.

Furthermore, in the rack for fixed-point monitoring of the temperature sensor, the first connecting plate is arranged on the vertical side wall of each vertical upright, and the first connecting plate between two of the four vertical uprights is connected with the connecting rod.

Furthermore, the frame for fixed-point monitoring of the temperature sensor comprises a motor fixing mounting plate, a driving motor, a first driving wheel, a first transmission chain, a first driven wheel, a transmission assembly, a supporting slide rail, a supporting plate and a movable sensor mounting bracket, wherein the motor fixing mounting plate is fixedly arranged on an upper connecting beam, the driving motor is fixedly arranged on the motor fixing mounting plate and is connected with the first driving wheel, the first driving wheel is connected with the first driven wheel through the first transmission chain, the first driven wheel is connected with the transmission assembly, the transmission assembly and the supporting slide rail are arranged on a first sensor mounting beam, a second sensor mounting beam and a third sensor mounting beam, the supporting plate is connected with the transmission assembly, the supporting plate is connected with the supporting slide rail in a sliding manner, and the movable sensor mounting bracket is connected with the supporting plate, the two movable sensors are arranged on the movable sensor mounting bracket.

Furthermore, the rack for fixed-point monitoring of the temperature sensor comprises four driven wheels II and a transmission chain II, wherein the four driven wheels II and the driven wheels I are arranged on the same rotating shaft, the four driven wheels II are respectively arranged on a sensor mounting beam I, a sensor mounting beam II and a sensor mounting beam III, the transmission chain II is arranged on the four driven wheels II, and the supporting disc is connected with the transmission chain II.

Further, foretell frame of temperature sensor fixed point monitoring, the movable sensor installing support includes spliced pole, bracing piece and two sensor support, the upper end and the supporting disk fixed connection of spliced pole, the lower tip fixed connection of bracing piece and spliced pole to spliced pole and bracing piece constitute "T" style of calligraphy structure, two sensor support set up the both ends at the bracing piece respectively, two sensor support and two movable sensor one-to-ones set up to movable sensor is fixed to be set up on sensor support.

Furthermore, in the rack for fixed-point monitoring of the temperature sensor, the four driven wheels are located at four corner positions of the diamond, and the section of the transmission chain is of the diamond shape.

The technical scheme shows that the utility model has the following beneficial effects: according to the rack for fixed-point monitoring of the temperature sensor, the fixed sensor is arranged at the center and four corner positions of the cross section where the rack is located through the combination of the fixed sensor and the movable sensor, so that temperature monitoring can be carried out on all points in the cross section range where the rack is located, the movable sensor can continuously move circularly in the range of the cross section occupied by the rack, the temperature of the blank area between the fixed temperature sensors is monitored, the reliability of temperature monitoring can be guaranteed, and omnibearing monitoring can be carried out in the space range of the rack.

Drawings

FIG. 1 is a front view of a rack for site monitoring of temperature sensors according to the present invention;

FIG. 2 is a first top view of a rack for site monitoring of temperature sensors according to the present invention;

FIG. 3 is a second top view of the rack for fixed-point monitoring of the temperature sensor according to the present invention;

fig. 4 is a schematic structural view of a movable sensor mounting bracket according to the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Examples

The rack for fixed-point monitoring of the temperature sensor shown in fig. 1 and 2 comprises four vertical upright posts 1, four upper connecting beams 2, a first sensor mounting beam 3, a second sensor mounting beam 4, a third sensor mounting beam 5, a central temperature sensor 6, four corner monitoring sensors 7, two movable sensors 8 and a movable sensor driving device 9, wherein the upper ends of the four vertical upright posts 1 are connected through the four upper connecting beams 2, the four vertical upright posts 1 and the four upper connecting beams 2 form a rectangular frame structure, the first sensor mounting beam 3, the second sensor mounting beam 4 and the third sensor mounting beam 5 are arranged in parallel, the first sensor mounting beam 3, the second sensor mounting beam 4 and the third sensor mounting beam 5 are arranged on the upper connecting beam 2, and the second sensor mounting beam 4 is positioned between the first sensor mounting beam 3 and the third sensor mounting beam 5, center temperature sensor 6 sets up on sensor installation crossbeam two 4, four bight monitoring sensor 7 sets up on sensor installation crossbeam one 3 and sensor installation crossbeam three 5, activity sensor drive arrangement 9 sets up on sensor installation crossbeam one 3, sensor installation crossbeam two 4 and sensor installation crossbeam three 5, two activity sensors 8 and activity sensor drive arrangement 9 are connected, activity sensor drive arrangement 9 can drive two activity sensors 8 and remove in the rectangular frame that four vertical stand 1 and four upper connection crossbeam 2 constitute.

In order to perform global temperature control monitoring on the production line, the central temperature sensor 6 is located at the center of the rectangular cross section where the four upper connecting beams 2 are located. Four corner monitoring sensors 7 are located at the four corner positions of the rectangular cross section where the four upper connecting beams 2 are located. Thus, a structure with four central distribution points is formed, and temperature control monitoring at a fixed position is carried out.

In addition, the lower end of the vertical upright post 1 is provided with a fixed mounting plate 11, a group of reinforcing rib plates 12 are arranged between the fixed mounting plate 11 and the vertical upright post 1, and the group of reinforcing rib plates 12 are arranged in an annular array mode. The vertical side walls of the vertical upright posts 1 are provided with first connecting plates 13, and the first connecting plates 13 between two of the four vertical upright posts 1 are connected with connecting rods 14.

The movable sensor driving device 9 shown in fig. 3 comprises a motor fixing mounting plate 91, a driving motor 92, a driving wheel 93, a driving chain 94, a driven wheel 95, a driving assembly 96, a supporting slide rail 97, a supporting plate 98 and a movable sensor mounting bracket 99, wherein the motor fixing mounting plate 91 is fixedly arranged on the upper connecting beam 2, the driving motor 92 is fixedly arranged on the motor fixing mounting plate 91, the driving motor 92 is connected with the driving wheel 93, the driving wheel 93 is connected with the driven wheel 95 through the driving chain 94, the driven wheel 95 is connected with the driving assembly 96, the driving assembly 96 and the supporting slide rail 97 are respectively arranged on the sensor mounting beam 3, the sensor mounting beam two 4 and the sensor mounting beam three 5, the supporting plate 98 is connected with the driving assembly 96, and the supporting plate 98 is connected with the supporting slide rail 97 in a sliding manner, the movable sensor mounting bracket 99 is connected with the supporting plate 98, and the two movable sensors 8 are arranged on the movable sensor mounting bracket 99. The transmission assembly 96 comprises four driven wheels two 961 and a transmission chain two 962, one of the four driven wheels two 961 and the driven wheel one 95 are arranged on the same rotating shaft, the four driven wheels two 961 are respectively arranged on a sensor mounting cross beam one 3, a sensor mounting cross beam two 4 and a sensor mounting cross beam three 5, the transmission chain two 962 is sleeved on the four driven wheels two 961, and the support disc 98 is connected with the transmission chain two 962.

The driving motor 92 drives the first driving wheel 93 to rotate, the first driving wheel 93 drives the first driven wheel 95 to rotate through the first transmission chain 94, and the first driven wheel 95 drives the supporting plate 98 to rotate through the transmission assembly 96, so that the two movable sensors 8 move in the space range of the support and perform temperature monitoring at different positions.

The movable sensor mounting bracket 99 shown in fig. 4 includes a connecting column 991, a supporting rod 992 and two sensor brackets 993, the upper end of the connecting column 991 is fixedly connected with a supporting disk 98, the lower end of the supporting rod 992 is fixedly connected with the connecting column 991, and the connecting column 991 and the supporting rod 992 form a structure in the shape of a 'T', the two sensor brackets 993 are respectively arranged at the two ends of the supporting rod 992, the two sensor brackets 993 and two movable sensors 8 are arranged in a one-to-one correspondence manner, and the movable sensors 8 are fixedly arranged on the sensor brackets 993. The four second driven wheels 961 are positioned at the four corner positions of the diamond, and the section of the second transmission chain 962 is of a diamond shape.

The central temperature sensor 6 is positioned in the center of the diamond-shaped section occupied by the second transmission chain 962, and the four corner monitoring sensors 7 are distributed outside the diamond-shaped section occupied by the second transmission chain 962.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that modifications can be made by those skilled in the art without departing from the principle of the present invention, and these modifications should also be construed as the protection scope of the present invention.

Claims (9)

1. The utility model provides a frame of temperature sensor fixed point monitoring which characterized in that: comprises four vertical columns (1), four upper connecting beams (2), a sensor mounting beam I (3), a sensor mounting beam II (4), a sensor mounting beam III (5), a central temperature sensor (6), four corner monitoring sensors (7), two movable sensors (8) and a movable sensor driving device (9), wherein the upper ends of the four vertical columns (1) are connected through the four upper connecting beams (2), the four vertical columns (1) and the four upper connecting beams (2) form a rectangular frame structure, the sensor mounting beam I (3), the sensor mounting beam II (4) and the sensor mounting beam III (5) are arranged in parallel, and the sensor mounting beam I (3), the sensor mounting beam II (4) and the sensor mounting beam III (5) are arranged on the upper connecting beams (2), sensor installation crossbeam two (4) are located between sensor installation crossbeam one (3) and sensor installation crossbeam three (5), central temperature sensor (6) set up on sensor installation crossbeam two (4), four bight monitoring sensor (7) set up on sensor installation crossbeam one (3) and sensor installation crossbeam three (5), activity sensor drive arrangement (9) set up on sensor installation crossbeam one (3), sensor installation crossbeam two (4) and sensor installation crossbeam three (5), two activity sensors (8) are connected with activity sensor drive arrangement (9), activity sensor drive arrangement (9) can drive two activity sensors (8) and remove in the rectangular frame that four vertical stand (1) and four upper connecting beam (2) constitute.

2. The temperature sensor site-specific monitoring rack of claim 1, wherein: the central temperature sensor (6) is positioned at the central position of the rectangular section where the four upper connecting cross beams (2) are positioned.

3. A temperature sensor site monitoring rack according to claim 1 or 2, characterized by: the four corner monitoring sensors (7) are positioned at four corner positions of the rectangular section where the four upper connecting cross beams (2) are positioned.

4. The temperature sensor site-specific monitoring rack of claim 1, wherein: the lower end of the vertical upright post (1) is provided with a fixed mounting plate (11), a group of reinforcing rib plates (12) are arranged between the fixed mounting plate (11) and the vertical upright post (1), and the group of reinforcing rib plates (12) are arranged in an annular array mode.

5. A temperature sensor site monitoring rack according to claim 1 or 4, characterized by: the vertical upright post is characterized in that first connecting plates (13) are arranged on the vertical side walls of the vertical upright posts (1), and connecting rods (14) are connected to the first connecting plates (13) between two of the four vertical upright posts (1).

6. The temperature sensor site-specific monitoring rack of claim 1, wherein: the movable sensor driving device (9) comprises a motor fixing mounting plate (91), a driving motor (92), a driving wheel I (93), a driving chain I (94), a driven wheel I (95), a driving assembly (96), a supporting slide rail (97), a supporting plate (98) and a movable sensor mounting bracket (99), wherein the motor fixing mounting plate (91) is fixedly arranged on the upper connecting beam (2), the driving motor (92) is fixedly arranged on the motor fixing mounting plate (91), the driving motor (92) is connected with the driving wheel I (93), the driving wheel I (93) is connected with the driven wheel I (95) through the driving chain I (94), the driven wheel I (95) is connected with the driving assembly (96), and the driving assembly (96) and the supporting slide rail (97) are arranged on a sensor mounting beam I (3), a sensor mounting beam II (4) and a sensor mounting beam III (5), the supporting plate (98) is connected with the transmission assembly (96), the supporting plate (98) is in sliding connection with the supporting slide rail (97), the movable sensor mounting bracket (99) is connected with the supporting plate (98), and the two movable sensors (8) are arranged on the movable sensor mounting bracket (99).

7. The temperature sensor fixed-point monitoring rack of claim 6, wherein: the transmission assembly (96) comprises four driven wheels II (961) and a transmission chain II (962), one of the four driven wheels II (961) and the driven wheel I (95) are arranged on the same rotating shaft, the four driven wheels II (961) are respectively arranged on a sensor mounting cross beam I (3), a sensor mounting cross beam II (4) and a sensor mounting cross beam III (5), the transmission chain II (962) is sleeved on the four driven wheels II (961), and the supporting disc (98) is connected with the transmission chain II (962).

8. The temperature sensor site-specific monitoring rack of claim 7, wherein: activity sensor installing support (99) are including spliced pole (991), bracing piece (992) and two sensor support (993), the upper end and supporting disk (98) fixed connection of spliced pole (991), the lower tip fixed connection of bracing piece (992) and spliced pole (991) to spliced pole (991) and bracing piece (992) constitute "T" style of calligraphy structure, two sensor support (993) set up the both ends at bracing piece (992) respectively, two sensor support (993) and two activity sensor (8) one-to-one set up to activity sensor (8) are fixed to be set up on sensor support (993).

9. The temperature sensor site-specific monitoring rack of claim 8, wherein: the four driven wheels II (961) are positioned at the four corner positions of the diamond shape, and the section of the transmission chain II (962) is of the diamond shape.

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